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NUS LABORATORY
IONIZING RADIATION SAFETY MANUAL
Document No. : NUS/OSHE/M/04
Version No. : 01
Issue Date : March 01 2012
Revision Date : March 24 2015
Officer in-charge : Mr. Pramoth Chandrikamohan
Approved by : Mr. Saravanan s/o Gunaratnam
Office of Safety, Health
and Environment
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Amendment
Revision
No.
Released Date Description Prepared by
00 1 Mar 2012 New manual Pramoth
01 24 Mar 2015 1. Section 2.2 Revised
from NUS Radiation
Safety Policy to NUS
General Safety and
Health Policy
2. Revision of Centre for
Radiation Protection and
Nuclear Science to
Radiation Protection and
Nuclear Science
Department
3. Revision to contact
phone number for UHC
in Section 27.2
Pramoth
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TABLE OF CONTENTS _______________________________________________ PAGE
1 INTRODUCTION .......................................................................................................................... 7
2 RADIATION SAFETY PROGRAM ADMINISTRATION ......................................................... 7
2.1 APPLICABLE LEGISLATION ON RADIATION ................................................................ 7
2.2 NUS GENERAL SAFETY AND HEALTH POLICY ............................................................ 8
2.3 NUS SAFETY DIRECTIVES ................................................................................................. 8
2.4 ROLES AND RESPONSIBILITIES ....................................................................................... 9
NUS PRESIDENT ............................................................................................................ 9
NUS INSTITUTIONAL LABORATORY SAFETY COMMITTEES (ILSC) ................ 9
DEANS AND HEAD OF DEPARTMENTS .................................................................... 9
PRINCIPAL INVESTIGATOR AND SUPERVISOR ................................................... 10
FACULTY SAFETY & HEALTH OFFICER ................................................................ 11
RADIATION WORKERS .............................................................................................. 12
RADIATION SAFETY OFFICER (RSO) ...................................................................... 13
UNIVERSITY HEALTH CENTRE (UHC) ................................................................... 14
3 RISK ASSESSMENT ................................................................................................................... 14
3.1 PROJECT RISK ASSESSMENT SCHEME ......................................................................... 15
3.2 LABORATORY OSH CERTIFICATION SCHEME ........................................................... 15
4 LICENSES .................................................................................................................................... 15
4.1 RADIOACTIVE MATERIALS LICENSE .......................................................................... 16
4.2 IRRADIATING APPARATUS LICENSE ............................................................................ 17
4.3 LICENSE EXEMPTIONS: .................................................................................................... 19
5 MEDICAL SURVEILLANCE ..................................................................................................... 19
5.1 PRE-PLACEMENT EXAMINATION .................................................................................. 19
5.2 PERIODIC MEDICAL EXAMINATION ............................................................................. 20
6 TRAINING ................................................................................................................................... 20
6.1 INITIAL TRAINING ............................................................................................................. 20
6.2 LAB SPECIFIC TRAINING ................................................................................................. 20
6.3 REFRESHER TRAINING ..................................................................................................... 20
6.4 RADIATION AWARENESS TRAINING ............................................................................ 20
7 REGULATORY DOSE LIMITS ................................................................................................. 20
7.1 PRENATAL MONITORING ................................................................................................ 21
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7.2 ALARA PRINCIPLE ............................................................................................................. 21
8 DOSE CONTROL / RADIATION PROTECTION ..................................................................... 22
8.1 TIME, DISTANCE AND SHIELDING PRINCIPLE ........................................................... 23
8.2 ENGINEERING CONTROLS .............................................................................................. 23
8.3 ADMINISTRATIVE CONTROLS: ...................................................................................... 24
8.4 PERSONAL PROTECTIVE EQUIPMENT ......................................................................... 25
9 RADIATION LABORATORY SAFETY ..................................................................................... 26
9.1 GENERAL SAFETY GUIDELINES .................................................................................... 26
9.2 DESIGN AND SETUP OF RADIATION USE AREA ........................................................ 26
10 PROCUREMENT AND RECEIPT OF RADIOACTIVE MATERIALS ...................................... 28
10.1 RADIOACTIVE MATERIAL PROCUREMENT ............................................................ 28
10.2 RECEIPT OF RADIOACTIVE MATERIALS.................................................................. 28
11 PROCUREMENT AND COMMISSIONING RADIATION PRODUCING MACHINES ........... 29
12 INVENTORY OF RADIOACTIVE MATERIALS .................................................................. 29
13 TRANSFER OF RADIATION SOURCES .............................................................................. 30
13.1 TRANSFER OF RADIOACTIVE MATERIALS ............................................................. 30
WITHOUT USING MOTORIZED VEHICLES ............................................................ 30
USING MOTORIZED VEHICLES (PERSONAL AND PUBLIC VEHICLES) .......... 30
13.2 TRANSFER OF RADIATION PRODUCING MACHINES ............................................ 30
14 STORAGE OF RADIATION SOURCES ................................................................................ 31
15 RADIATION POSTINGS AND WARNINGS ......................................................................... 31
16 RADIATION INSTRUMENTATION ...................................................................................... 32
17 CONTAMINATION MONITORING ...................................................................................... 33
17.1 CONTAMINATION SURVEYS ....................................................................................... 34
PANCAKE AND END WINDOW GM DETECTORS ................................................. 35
SCINTILLATION DETECTORS ................................................................................... 35
17.2 HOW TO PERFORM A CONTAMINATION SURVEY ................................................. 36
17.3 CONTAMINATION ACTION LEVELS........................................................................... 37
17.4 DECONTAMINATION PROCEDURES .......................................................................... 38
DECONTAMINATION OF SKIN ................................................................................. 38
DECONTAMINATION OF CLOTHING ...................................................................... 38
DECONTAMINATION OF EYES ................................................................................ 38
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DECONTAMINATION OF LAB FLOOR AND BENCHES ........................................ 38
18 EXTERNAL EXPOSURE MONITORING .............................................................................. 38
18.1 AREA EXPOSURE MONITORING ................................................................................. 38
ENERGY COMPENSATED GM DETECTORS ........................................................... 39
IONIZATION CHAMBERS........................................................................................... 39
EXPOSURE RATE SURVEYS ...................................................................................... 39
HOW TO PERFORM A SURVEY ................................................................................ 40
18.2 PERSONNEL EXPOSURE MONITORING ..................................................................... 41
19 INTERNAL EXPOSURE MONITORING ............................................................................... 42
19.1 THYROID MONITORING ............................................................................................... 42
19.2 URINE ANALYSIS ........................................................................................................... 43
20 DISPOSAL OF RADIOACTIVE WASTE ............................................................................... 43
20.1 GENERAL REQUIREMENTS .......................................................................................... 43
20.2 STORAGE AND HANDLING REQUIREMENTS .......................................................... 44
20.3 WASTE DISPOSAL REQUIREMENTS ........................................................................... 45
21 ACCIDENT / INCIDENT REPORTING AND INVESTIGATION ........................................ 45
21.1 RADIATION ACCIDENTS .............................................................................................. 45
21.2 ACCIDENT RESPONSE PROCEDURES ........................................................................ 46
22 RADIATION EMERGENCIES ................................................................................................ 47
23 RADIOACTIVE MATERIAL SPILL RESPONSE .................................................................. 47
23.1 MINOR SPILLS ................................................................................................................. 48
23.2 MAJOR SPILLS ................................................................................................................ 48
24 CHECKING OF LEAKAGE/ BREAKAGE OF SEALED SOURCE ...................................... 49
25 DECOMMISSIONING ............................................................................................................. 49
25.1 DECOMMISSIONING OF LABS USING RADIOACTIVE MATERIAL ...................... 49
25.2 DECOMMISSIONING OF RADIATION PRODUCING MACHINES ........................... 50
25.3 DECOMMISSIONING OF EQUIPMENT USING RADIOACTIVE MATERIAL ......... 50
26 RADIATION LABORATORY INSPECTIONS: ..................................................................... 51
27 EMERGENCY PHONE NUMBERS AND SAFETY PERSONNEL CONTACTS ................ 51
27.1 EMERGENCY PHONE NUMBERS ................................................................................ 51
27.2 UNIVERSITY HEALTH CENTRE (UHC) ...................................................................... 51
27.3 NEAREST HOSPITAL ...................................................................................................... 52
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27.4 OFFICE OF SAFETY, HEALTH AND ENVIRONMENT (OSHE) ................................ 52
28 LIST OF APPENDICES ........................................................................................................... 53
Appendix A: Ionizing Radiation Occupational Dose Limits ........................................................ 54
Appendix B: Radionuclide Exemption Quantitiy Limits ............................................................. 58
Appendix C: Annual Limits on Intake (ALI) for Radiation Workers .......................................... 63
Appendix D: Limits for Contamination of Surfaces .................................................................... 68
Appendix E: Request for Funding for Occupational Health Related Medical Services
(OSHE/51/D01) ............................................................................................................................ 71
Appendix F: Fact Sheets of Commonly Used Isotopes ................................................................ 73
Appendix G: Radioactive Package Receipt and Inspection Form ....................................................
Appendix H: Radiation Machine Inspection and Survey Form .................................................... 79
Appendix I: Radioactive Material Inventory Form ...................................................................... 80
Appendix J: Standard Symbol For Designating Any Ionising Radiation Hazard ............................ 80
Appendix K: Portable Radiation Survey Meter Operation Procedure .......................................... 82
Appendix L: Liquid Scintillation Counter Operation/Wipe Test Procedure ................................ 85
Appendix M: Radioactive Material User Monthly Survey Form ................................................. 86
Appendix N: Radiation Dose Record Transfer Form .........................................................................
Appendix O: Request for Disposal of Radioactive Waste Form (OSHE/F/RS/01) ..................... 87
Appendix P: Radioactive waste container label ........................................................................... 88
Appendix Q: Sealed Source Leak Test Procedure ........................................................................ 89
Appendix R: Sealed Source Leak Test Report ............................................................................. 91
Appendix S: Radiation Laboratory Inspection Checklist .................................................................
Appendix T: RPNSD Service Request Form ............................................................................... 92
TABLE 1 Singapore Regulatory and NUS ALARA Radiation Dose Investigation Levels .......... Error!
Bookmark not defined.24
TABLE 2 Summary of Use Characteristics of Various Meters ........................................................... 35
TABLE 3 Summary of Efficiencies of Various Detectors to Commonly Used Radionuclides .... Error!
Bookmark not defined.37
TABLE 4 LSC Detection Efficiencies of Commonly Used Radionuclides ......................................... 38
TABLE 5 Regulatory Exposure Rate Limits for Various Radiation Use Conditions .......................... 41
FIGURE 1 Radioactive Material Licensing Guide............................................................................... 19
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FIGURE 2 Irradiating Apparatus Licensing Guide .............................................................................. 20
1 INTRODUCTION
Research and Development at National University of Singapore (NUS) involves extensive
use of different sources of ionizing radiation. The sources of ionizing radiation are broadly classified
into radioactive materials and radiation producing machines. This Ionizing Radiation Safety manual is
intended to provide guidance for establishing safe work procedures and prudent practices that will
improve safety while using all ionizing radiation sources. This manual forms a part of the Radiation
Safety Program (RSP) administered by Office of Safety, Health and Environment (OSHE) to ensure
safe use of radiation at NUS. The program ensures that any activity involving use of radiation is
conducted in a manner as to protect and minimize one’s risks to health, safety and property.
This Manual should be used in conjunction with other laboratory safety manuals, i.e.:
NUS General Laboratory Safety Manual – provides safety and health requirements on issues
common to all laboratories, for example, commissioning and decommissioning of laboratory, laboratory
sign posting, personal protective equipment, first aid, contractors management, etc.
NUS Laboratory Chemical Safety Manual – provides safety and health requirements for
working with chemical substances, such as flammable materials, toxic chemicals, acids and base,
peroxides, poisons, etc.
NUS Laboratory Biorisk Management Manual – provides safety and health requirements for
working with materials of biological origin, including genetically modified organisms (GMOs) in
laboratories.
All personnel involved in ionizing radiation work are required to read and understand the content of this
manual before they start work. They should be sufficiently trained and be equipped with the necessary
knowledge, skill and techniques to to prevent or minimize conditions thatthreaten the safety and health of
his/her own and others in the vicinity. The possession and use of ionizing radiation sources are subjected
to licensing. Staff and students must ensure that they are licensed/ authorized to work with irradiating
apparatus/ sources or be adequately supervised while working with such sources.
2 RADIATION SAFETY PROGRAM ADMINISTRATION
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2.1 APPLICABLE LEGISLATION ON RADIATION
The Radiation Protection and Nuclear Science Department (RPNSD), part of National Environment
Agency, is the national authority for radiation protection and nuclear safety in Singapore. It administers
and enforces the Radiation Protection Act and Regulations through a system of licensing, notification,
authorization, inspection, and enforcement. For more information, visit
http://app2.nea.gov.sg/topics_radiation.aspx.
Radiation Protection (Ionising Radiation) Regulations, regulates the manufacture, possession, use and
disposal of all sources of ionizing radiation.
Annual dose limit for radiation workers and members of public are specified in the Second Schedule of
the Radiation Protection (Ionising Radiation) Regulations (see Appendix A).
The use of radionuclide activity and activity concentrations above which the Radiation Protection
(Ionizing Radiation) Regulations apply is provided in First Schedule (see Appendix B)
The Annual Limit of Intake(ALI) for various radionuclides for a radiation worker are specified in Third
Schedule of the Radiation Protection (Ionising Radiation) Regulations (see Appendix C).
The radioactive contamination limits are specified in Fifth Schedule of the Radiation Protection (Ionising
Radiation) Regulations (see Appendix D).
Radiation Protection (Transport of Radioactive Materials) Regulations regulates transport of radioactive
materials on public roads, highways and waterways. The Regulations also specify requirements for
packaging and packages.
2.2 NUS GENERAL SAFETY AND HEALTH POLICY
The NUS Senior Management has defined the NUS General Safety & Health Policy that formally
expresses NUS’s commitment to ensuring a high standard of occupational safety and health for its
staff, students, visitors and contractors. The policy emphasizes safety ownership and establishment of
safety and health culture. The policy also provides the responsibilities of various stakeholders in
ensuring a safe working environment. Staff and students must comply with the requirements of this
policy. The policy can be accessed through the following link:
http://www.nus.edu.sg/osh/policies.htm
2.3 NUS SAFETY DIRECTIVES
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The NUS Safety Directives provide safety and health governance on specific issues. Refer to the
following website for the Directives:
http://www.nus.edu.sg/osh/policies.htm
The Institutional Laboratory Safety Committee (ILSC) is the University level committee to oversee the
development and implementation of the Radiation Safety Program. The Office of Safety, Health and
Environment (OSHE) is the administrator of this Program.
2.4 ROLES AND RESPONSIBILITIES
NUS PRESIDENT
The President of the NUS represents the University as the Employer. The ultimate responsibility for
safety and health in the University rests with the President. The President may delegate the authority and
responsibility to the ILSC, Deans, Administrators, and HODs for the effective supervision of the
occupational safety and health of staff and students under his/ her management.
The ILSC and OSHE can report any incident or conditions of non-compliance to the NUS President,
Senior Deputy President, Provost, Deputy Presidents and Vice Presidents, who are entitled to partially or
fully close the laboratories or facilities until all safety issues are addressed.
NUS INSTITUTIONAL LABORATORY SAFETY COMMITTEES (ILSC)
Institutional Laboratory Safety Committee (ILSC) has been formed to serve as an advisory to review
standards and guidance documents related to general laboratory safety at the university level.
The ILSC is appointed by the Provost. The Terms of Reference for the ILSC are:
i. Review and approve the NUS Radiation Safety Program and NUS Chemical Safety Program
documents including safety manuals, SOPs and directives and recommend revisions to OSHE.
ii. Review any radiation safety audit and inspection findings conducted by OSHE or other
independent parties on faculties and departments.
iii. Serve in an advisory capacity to OSHE on all chemical, radiation and physical safety related
matters pertaining to laboratories.
iv. To endorse risk assessments that cannot be effectively evaluated at the departmental or faculty
level, including appeals by PIs.
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The Committee will be assisted by the Occupational Safety and Health Management Division of OSHE.
DEANS AND HEAD OF DEPARTMENTS
All Deans and HODs of respective lab-based faculties and departments will ensure that their respective
faculty or departmental radiation SOPs, standards and guidance documents as well as components of the
Radiation Safety Program implemented at departmental and faculty level are in order and reviewed
periodically. Deans or HODs should empower Faculty Safety & Health Officers and personnel appointed
to assume safety responsibilities (herein called the "Departmental Safety Committee"), to coordinate the
NUS Radiation Safety Programme at the faculty and departmental level.
The HOD shall appoint a competent person to coordinate waste disposal in the Department.
PRINCIPAL INVESTIGATOR AND SUPERVISOR
Principal investigators are directly responsible for compliance with all regulations governing radiation
safety in the laboratory, and for safety of individuals working under their supervision. Principal
investigators are obligated to:
Be aware of and comply with requirements (regulatory and University) pertaining to the use
of radiation sources and also establish and maintain a safe working environment.
Ensure all required radiation licenses exist and are current before any work with radiation is
commenced. Ensure that all the radiation workers in his group have valid radiation worker
licenses.
Ensure that all personnel have completed relevant OSHE radiation safety trainings before any
work with radiation is commenced. Maintain relevant training records.
Ensure that individuals are properly supervised and trained on laboratory specific safe work
practices. Ensure that all individuals are aware of and trained on all relevant safety documents
(SOPs, manuals etc.,). Ensure all individuals are aware of procedures for identifying emergency
situations and following emergency response protocols.
Perform a risk assessment of experiments and protocols involving use of radiation sources.
Identify risks, evaluate existing risk controls, ensure existing risk levels are acceptable and also
identify and implement any additional controls required to minimize risk. .
Maintain an accurate record of the inventory of all sources of radiation in his/her lab.
Records/logs on receipt, use and disposal of all sources of radiation should be current and
updated as and when required.
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Ensure all sources of radiation are stored and used in a manner that minimizes exposure to
themselves and other individuals.
Implement controls to ensure all sources of radiation are accessed and used only by
individuals licensed to access/use them. Prevent unauthorized removal or tampering or loss of
all radiation sources.
Post appropriate warnings and labels as required by this manual to ensure adequate
communication of radiation hazards.
Notify Faculty Safety and Health Officer of any changes in license application information
including changes in radiation use, addition or termination of radiation workers, or changes of
areas where radiation sources are used or stored.
Ensure that radiation safety surveys, including contamination surveys, exposure surveys and
leak tests, are conducted as required by this manual, and maintain records for review.
Ensure necessary resources needed to ensure good safety practices and adequate infrastructures
for the safe operation of the lab are available. This includes (but are not limited to) any
shielding, waste containers, exposure and contamination monitors, and any other resources
that are required for minimizing radiation exposure.
Ensure all radiation monitoring devices owned by the group are calibrated annually.
Ensure all sources of radiation are transferred/disposed and also ensure no residual
contamination exists before vacating any radiation use area or lab. PI should maintain any
relevant records for review.
Report all incidents/accidents related to radiation work which include (but not limited to) loss
of radioactive material, spills or discharges, real or suspected intakes of radioactive material
by laboratory personnel, and real or suspected increased exposure to radiation during use of
radiation producing machines. PIs should cooperate with any incident investigation by
regulators and OSHE.
Ensure the radioactive wastes are properly sealed and placed in the designated bags and properly
disposed. The PI shall appoint a competent person to coordinate waste disposal in the laboratory.
Maintain records related to training, exposure and contamination surveys, leak tests of sealed
sources, inventory of radiation sources, transfer and transport of radiation sources, radioactive
waste disposal and decommissioning labs.
Ensure all visitors and maintenance personnel accessing restricted radiation use areas are warned
of radiation hazards in the laboratory and follow applicable safety rules.
FACULTY SAFETY & HEALTH OFFICER
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Faculty Safety and Health Officer (FSHO) are responsible for verifying PIs compliance with NUS
Radiation Safety program and directives. FSHO is obligated to:
Ensure that all radiation producing machines and radioactive materials used in the Faculty have
the appropriate radiation licenses.
Maintain a database of all radiation licenses pertaining to possession and use of radiation
producing machines and radioactive materials in the Faculty
Serve as intermediary in communication between regulators and license holders on license
applications, amendments,renewals and cancellations.
Facilitate radiation monitoring badge exchange between regulators and license holders and also
communicate dosimetry report to license holders.
Review radiation dosimetry reports of radiation workers and inform PI and RSO if the ALARA
limits set forth in this manual are exceeded.
Ensure periodical radiation surveys are being performed by PIs and also review the surveys to
determine if dose rates and contamination levels do not exceed limits set in this manual.
Ensure all PIs comply with radiation lab commissioning and decommissioning procedures and
verify the commissioning/decommissioning compliance. Ensure all radiation licenses are
cancelled after any decommissioning of labs or equipments or after any individual terminates
radition work.
Inform all incidents reported by PI to Radiation Safety Officer and help RSO in incident
investigation process.
Maintain records related to exposure records from regulators, internal radiation safety
inspections and incident investigations.
RADIATION WORKERS
All individuals working directly with sources of radiation are termed as radiation workers. Since the
workers, are the direct handlers of radiation sources, they have an important role in ensuring safety
and compliance. For this reason, it is critical that they be aware of the risks, safe practices and
requirements for use of radiation.
Radiation workers are obligated to:
Comply with this Radiation Safety Manual, regulatory requirements, as well as other university,
faculty and departmental specific safety manuals and SOPs.
Adhere to all risk controls identified and implemented by the PIs
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Obtain radiation worker license from regulators prior to working with sources of radiation.
Successfully complete relevant OSHE Radiation Safety Training prior to working with
sources of radiation. Radiation workers also must comply with refresher training
requirements.
Wear radiation monitoring badges at all times while using sources of radiation.
Practice principles of maintaining radiation dose ALARA (As Low As Reasonably
Achievable) in their work, and minimize the potential for exposures, contamination or release
of radioactive materials.
Monitor radiation exposure in radiation work areas and ensure the radiation levels are below
regulatory limits.
Monitor spread of radioactive material contamination and leakage of sealed sources and clean
any contamination or spills that occur in their work area
Report immediately any radioactive material spills, radiation equipment failure or any other
accidents/incidents to Principal Investigator.
Return the radiation dosimeter on time and report any loss or contamination of the dosimeter
to the FSHO. They also should immediately return radiation dosimeters at end of
employment or end of radiation work to FSHO.
Assist RSO with coordinating the radioactive waste disposal program
RADIATION SAFETY OFFICER (RSO)
The Radiation Safety Officer is responsible for implementing the Radiation Safety Program
established by OSHE. The RSO has been provided with the administrative authority by the ILSC to
enforce the radiation protection activities at NUS. RSO has the authority to temporarily suspend an
unsafe activities involving radiation deemed to be unsafe subject to review by the safety committee.
Duties of the Radiation Safety Officer include (but not limited to)
Develop and implement safety policy, manual, procedures and directives subject to the
approval by ILSC.
Liaise with regulatory agencies, faculties and departments in the ongoing implementation of the
University's Radiation Safety Program.
Restrict or suspend use and/or possession of sources of radiation whenever a significant
deviation from established regulatory and university requirements has occurred or when there
is threat to health or property.
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Perform bi-annual radiation safety inspection in all labs using radiation and report any non-
compliance to the PIs and ILSC.
Review and advise on work practices of radiation workers who received dose above ALARA
levels set forth in this manual.
Perform an investigation of all incidents/accidents related to radiation work at NUS and
submit investigation reports, as required, to the regulators, ILSC and to Senior Management.
Ensure that effective corrective actions are developed, implemented, and documented if
violations of regulations, or license or registration conditions, or program procedures are
identified.
Supervise and coordinate the radioactive waste storage and disposal program with licensed
radioactive waste collectors, the Faculty Safety & Health Officers and RPNSD.
Maintain a central database of all radiation license information related to radiation use at
NUS.
Develop, edit as necessary and provide all safety trainings related to safe use of radiation at
NUS.
Perform random surveys to monitor exposure levels and contamination levels in labs using
sources of radiation.
UNIVERSITY HEALTH CENTRE (UHC)
The UHC is the medical service provider for the Occupational Health Program of the University. UHC
provides any medical examinations that are required for obtaining radiation licenses from regulators.
UHC also provides ongoing annual medical examination for individuals who received more than three
tenths of the dose limits under Part I of the Second Schedule of the Radiation Protection (Ionising
Radiation) Regulations 2001 (see Appendix A)
3 RISK ASSESSMENT
All PIs are obligated to perform a thorough evaluation of risks and hazards associated with their projects
and identify and implement controls to minimize such risks. Where applicable, the risk assessment
should cover the following:
use of irradiating apparatus
use of radioactive materials
transfer and transport of radioactive materials (from one location to another)
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storage of radioactive materials
disposal of radioactive wastes
3.1 PROJECT RISK ASSESSMENT SCHEME
All PIs are responsible for the conduct of risk assessment prior to the commencement of research
projects. PIs can only commence work after their risk assessment has been approved. Refer to Research
Safety Compliance Form information at https://inetapps.nus.edu.sg/osh/portal/iorc.html for the
detailed risk assessment methodology, and submission and approval procedure.
The Project Risk Assessment is gradually being phased out, it will be replaced by the Laboratory OSH
Certification Scheme as described below.
3.2 LABORATORY OSH CERTIFICATION SCHEME
The Laboratory OSH Certification Scheme was launched to certify PIs who have effectively
implemented laboratory-based safety and health management system. Upon award of the certification to
the NUS Occupational Health and Safety Management System Standard for Laboratories, PIs would
generally not be required to submit risk assessments on a per-project basis. For more information, refer to
http://www.nus.edu.sg/osh/programmes/ohscert.htm.
4 LICENSES
The use of radioactive material and radiation producing machines are enforced by RPNSD by means
of licensing and imposing penalties on violations. Separate licenses are required for possession, for
use and for working with different sources of radiation.
All license applications, amendments, renewals and cancellations should be performed only by the
FSHO to enable OSHE to track radiation use at NUS. All completed license applications and the
cheque for the license fees should be sent to FSHO who will then forward them to RPNSD.
Blank license forms can be downloaded from the following link.
http://app2.nea.gov.sg/TemSub.aspx?pagesid=20080720226768161463&pagemode=live#radiation
The information on the license fees for different licenses can be found in the following link.
http://app2.nea.gov.sg/regulatory_info.aspx#licences The license fee covers the cost of any radiation
monitoring badge that may be required for radiation use. Upon approval of license application, the
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license and the radiation monitoring badge will be sent to the FSHO. All license approval letters,
renewal letters and radiation monitoring badges will be sent by RPNSD to the FSHO. RPNSD
requires approximately 45-60 days for processing license fees and issuing the license. So it is
advisable that users plan ahead of the radiation use
NEA administers a license qualifying test for all L5 and L6 license applicants. The passing of this test
is a prerequisite for obtaining the license. NEA will contact the applicants on the schedule and details
of the test. OSHE’s Ionizing Radiation Safety Training includes the information that can help
applicants successfully pass this license qualifying test.
L5, L6 and R1 license applications require a medical certificate completed within the past 12 months
to be attached. Please contact OSHE occupational health clinic for scheduling an appointment for
medical check up. Please refer to Section 5 on Medical Surveillance for more information.
Any change in the license information would require a license amendment. The change in information
along with the cheque for license amendment should be sent to FSHO immediately. The license
should be amended within two week of any change.
4.1 RADIOACTIVE MATERIALS LICENSE
This section applies to all radiation licenses required for using
1. Unsealed radioactive material (P-32, S-35, I-125, H-3 etc.,) used for labeling studies, in vitro
and in vivo studies, metabolic studies etc.,
2. Sealed radioactive materials used in equipment like thickness gauge, level gauge, static
eliminator, fluorescence analyser, gamma irradiator etc., (Note: the irradiating apparatus may need a
separate license. Please refer to Section 4.2 for further details.)
The different licenses that are required for using radioactive materials are -
L4 license- To keep or possess radioactive materials for use (other than sale).
This license authorizes the building or a group of buildings listed on the application to possess
radioactive materials that are listed on the application. Each Faculty/Research Institute holds one
radioactive material possession license (L4 license).
L6 license - To use, handle and transport radioactive materials (other than sale).
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This licenseauthorizes the PI to use the radioactive materials and machines that contain radioactive
materials listed on the L6 application. This L6 license needs to list the L4 license information. Each
PI is required to apply for radioactive material use license (L6 license)
R1 license- To register as a radiation worker.
This license authorizes a worker to perform radiation work under a PI with a valid L6 license. Each
worker performing experiments using the radioactive material under a PI should possess an R1
license. The license should list the L6 license information.
The licensing of radioactive material at NUS follows the structure showed in Figure 1.
Figure 1: Radioactive Material Licensing Guide
For more information or questions on radiation licensing contact the Radiation Safety Officer
4.2 IRRADIATING APPARATUS LICENSE
This section applies to all radiation licenses required for using
1. Irradiating apparatus with sealed sources ( Industrial radiography, industrial fluoroscopy,
gamma irradiator and any other equipment with sealed sources)
2. Irradiating apparatus emitting X-Rays (medical, dental and veterinary diagnostic and
therapeutic apparatus or any equipment emitting X-rays)
3. Particle accelerators (Van De Graaff accelerators, electrostatic generators, neutron generators,
linear accelerators, cyclotrons, betatrons, synchro-cyclotrons, synchrotrons etc.,)
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L3 license- To keep or possess an irradiating apparatus (other than sale).
. This license authorizes the lab or building to possess this irradiating apparatus. Each irradiating
apparatus should have its own L3 license.The Faculty or the Department holds this license.
L5 license- To use an irradiating apparatus (other than sale).
The license authorizes an individual to use a radiation producing equipment. The owner of the
machine or the person in charge who has responsibility to ensure safe operation of the apparatus
needs to apply for the L5 license. There is no need to obtain separate L5 license to use different
radiation producing equipment by the same user. All equipment (and its associated L3 license
number) used by a particular user must be listed on his/her L5 license application.
R1 license- To register as a radiation worker.
The license authorizes an individual to work with a radiation producing equipment. Each worker
performing experiments using the irradiating apparatus should possess an R1 license. There is no
need to obtain separate R1 license to work with different radiation producing equipment by the same
worker. All equipment (and its associated L5 license number) used by a particular worker must be
listed on his/her R1 license application. The licensing of radioactive material at NUS follows the
structure showed in Figure 2.
Figure 2: Irradiating Apparatus Licensing Guide
For more information or questions on radiation licensing contact the Radiation Safety Officer
EQUIPMENT 2 Faculty/Department holds
L3 License R1 R1 R1
Owner/Operator/In-charge– L5 license holder
EQUIPMENT 1 Faculty/Department holds
L3 License
EQUIPMENT 3 Faculty/Department holds
L3 License
Each equipment has its own L3 license
Owner or Operator has an L5 license and all equipments owned/operated by the person
are listed in this license
Radiation Workers have R1 license to use the equipment
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4.3 LICENSE EXEMPTIONS:
For students - Any student who in course of his studies performs any experiment using radiation is
exempted from R1 license under the condition that the radiation work is performed under continuous
supervision of a registered L6 or R1 license holder.
For unsealed radioactive materials – any research work involving radioactive materials in quantities
that fall below the activity or activity concentration prescribed in Appendix B does not require a L6
or R1 license from RPNSD. However, the use, storage and disposal of such exempted quantities
should follow the guidelines provided in this manual.
For sealed radioactive materials – any research work involving sealed radioactive material in
quantities that fall below 100 times the activity or activity concentration prescribed in Appendix B
does not require a L6 or R1 license from RPNSD. However, the researchers purchasing such sources
are required to ensure vendors/suppliers will take back the sources after their intended use at NUS.
For radiation producing machines - any electrical equipment which is not primarily intended to
produce ionizing radiation (such as Electron µscopes, cathode ray tubes, transmitting valves,
rectifying valves, image converters and television tubes) and which does not produce a radiation level
of more than 5 µSv/h at a distance of 5 cm from any accessible surface
5 MEDICAL SURVEILLANCE
5.1 PRE-PLACEMENT EXAMINATION
All L5/ L6/ R1 radiation license applicants are required to attach a report of medical examination
performed within the past 12 months along with their license application. The physical medical
examination can be conducted at the Occupational Health Clinic in OSHE. The funding for the medical
examination should be approved prior to approaching the clinic for the medical exam. The Request for
Funding for Occupational Health Related Medical Services form is provided in Appendix E should
be completed and submitted to the FSHO for approval. The form should be mailed to the clinic to
either
Nurse Kim @ [email protected] , 6516 7333; Goh Sha Wee @ [email protected] , 6601 1781.
The clinic will then schedule an appointment for performing the medical examination.
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5.2 PERIODIC MEDICAL EXAMINATION
The PI shall arrange medical examination once a year for every radiation worker who is receiving a sum
of radiation doses which is greater than three-tenths of the appropriate dose limit permitted under Part I
of the Second Schedule of the Radiation Protection (Ionising Radiation) Regulations 2001 (see
Appendix A) in any calendar year. Medical examination may be required if there is change in irradiating
equipment used or change in health status of the radiation worker. E.g. immuno-compromise or
pregnancy. This can be performed at the Occupational Health Clinic in OSHE
6 TRAINING
6.1 INITIAL TRAINING
All individuals applying for radiation license from RPNSD for use or working with sources of radiation
must undergo Radiation Safety Training relevant to their respective use of radiation. More information
on all the trainings provided by OSHE and the training registration details can be found at
https://inetapps.nus.edu.sg/osh/portal/shmgt/ssts.html
6.2 LAB SPECIFIC TRAINING
In addition to the mandatory training mentioned above, PIs may conduct safety training on topics
specifically related to the job being performed by the radiation workers.
6.3 REFRESHER TRAINING
Within two years of completing the OSHE Radiation Safety Training, all radiation workers are required
to retake the OSHE Radiation Safety Training to refresh the safety and health knowledge. The training is
updated and revised annually by OSHE.
6.4 RADIATION AWARENESS TRAINING
All individuals who are interested in increasing the awareness of safe use of radiation can undergo the
OSHE’s Radiation Awareness Training. The completion of the awareness training does not satisfy the
OSHE training requirement to handle radioactive material or radiation producing machines
7 REGULATORY DOSE LIMITS
Annual dose limit for radiation workers and members of public are specified in the Second Schedule of
the Radiation Protection (Ionising Radiation) Regulations (see Appendix A). Occupational external and
internal exposure from ionizing radiation should be controlled such that no individual shall receive a
Page | 21
radiation dose in excess of these limits. It should be noted that the dose limits for a radiation worker and
an individual member of the public are different.
The Radiation Protection (Ionizing Radiation) Regulations specifies the Annual Limit on Intake (ALI) of
a radionuclide for radiation workers. ALI is defined as the activity of a radionuclide which on intakeinto
the human body, would provide an exposure equal to the dose limit specified in Part I of the Second
Schedule. Different radio-nuclides have different values of ALI (see Appendix C on ALI for Radiation
Workers). Some radio-nuclides may concentrate in certain organs, causing these organs to receive
particularly high doses. Once taken up by the body, the retention and the exposure will be subjected to
excretion rate of the radionuclide from the body.
7.1 PRENATAL MONITORING
The dose limits for a pregnant worker is substantially lower than a normal radiation worker. All radiation
workers should be aware and understand the special precautions concerning exposure during
pregnancy, especially that the dose equivalent to the embryo or fetus from occupational exposure of
the expectant mother should not exceed 2 mSv for the entire gestation period. If possible, laboratory
workers who are pregnant or breast-feeding should not use volatile radioactive materials and have
extra precaution to prevent intake of radioactive materials. As a radiation worker, if you are pregnant,
planning to become pregnant or simply would like more information, please contact the Radiation
Safety Officer who will arrange a meeting with you to discuss any particular concerns and review any
special precautions in radiation uses. The RSO will inform RPNSD and obtain special/extra radiation
monitoring badges to monitor the dose to the abdomen.
7.2 ALARA PRINCIPLE
ALARA is the acronym for “As Low As Reasonably Achievable”. National University of Singapore
is committed to adoption of the principles of maintaining radiation doses to all individuals ALARA
(As Low As Reasonably Achievable) when working with sources of radiation. ALARA principle
forms the foundation of NUS Radiation Safety Program and ensures that every reasonable effort is
made to maintain exposures to ionizing radiation as far below the regulatory dose limits as practical.
As a result NUS has setup three investigation levels to ensure regulatory limits are not exceeded at
any time.
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Table 1: Singapore Regulatory and NUS ALARA Radiation Dose Investigation Levels
Exposure Location
Regulatory
Limit
ALARA
Level 1
ALARA
Level 2
ALARA
Level 3
Dose limit
per year
(mSv)
Dose
received in
any month
(mSv)
Dose
received in
any month
(mSv)
Dose
received in
any month
(mSv)
Effective dose (whole body) 50* 1 2 3
Equivalent dose in
the lens of the eye 150 3.125 6.25 9.375
the skin, hands and feet 500 10.4 20.83 31.23
Bioassay (Intake) 1 ALI 0.02 ALI 0.10 ALI 0.50 ALI * Provided users do not receive 100 mSv over a period of 5 years.
ALARA level 1: A monthly exposure of ALARA level 1, will result in the worker exceeding one-
fourths of the annual legal exposure limits or exceed 5% of Annual Limit for Intake of radionuclides.
If any individual receives a radiation dose in excess of ALARA level 1, a written notification is sent
to the user and PI. RSO will conduct an interview with the user to determine if dose levels can be
reduced. ILSC will be informed at next regularly scheduled meeting.
ALARA level 2: A monthly exposure of ALARA level 2, will result in the worker exceeding one-half
of the annual legal exposure limits or exceed 10% of Annual Limit for Intake of radionuclides. If any
individual receives a radiation dose in excess of ALARA level 2, a written notification is sent to the
user and PI. The PI must sign to acknowledge receipt of the report. RSO will conduct an interview
with the user to determine if dose levels can be reduced. ILSC will be informed will be notified after
the report is completed.
ALARA level 3: A monthly exposure of ALARA level 3, will result in the worker exceeding three-
fourths of the annual legal exposure limits or exceed 50% of Annual Limit for Intake of
radionuclides. If any individual receives a radiation dose in excess of ALARA level 3, the user must
suspend radiation work pending an investigation by RSO. A written report of the investigation is sent
to user, PI and ILSC. The PI must sign to acknowledge receipt of the report. The ILSC may authorize
continuing radiation work after review of the report.
8 DOSE CONTROL / RADIATION PROTECTION
The following principles should be followed to ensure the exposure and dose is maintained ALARA
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8.1 TIME, DISTANCE AND SHIELDING PRINCIPLE
Time: Radiation dose is proportional to the time spent in the radiation field. One can reduce the amount
of time handling radiation sources, to reduce the radiation dose received. Performing dry runs, having
implements or instruments close at hand, cleaning up contamination as is occurs, limiting the
presence in rooms with irradiating apparatus are examples of different methods of limiting exposure
time to radiation,.
Distance: The maximum practical distance should be maintained between any part of the person's body
and the radiation source. The dose received is inversely proportional to the square of the distance from
the radiation source. Doubling the distance between a radiation source and an individual will reduce
the dose by four times. Moving your storage container to the back of the refrigerator/freezer or
moving your waste container to the furthest location in the lab or workbench, using tweezers, forceps
and niptongs to handle vials, increasing the distance between control panels and the radiation
producing machines are some methods of increasing distance between an individual and radiation
source to reduce exposure.
Shielding: A shield in the radiation path will cause the radiation to be attenuated and scattered in various
directions so that the dose to the work will be reduced. The type of shielding used will depend on the type
and energy of the radiation. Perspex and plastic are ideal for shielding beta emitters like C-14, S-35, P-32
etc., and lead shields should be used for gamma emitting nuclides like Cs-137, I-125, Cr-51 etc., Lead
shields should never be used for shielding beta radiation, as it will result in generation of Bremsstrahlung
X-rays from the lead shield. Bench top shields and shielded waste containers and shielded storage
containers are used while using radioactive materials in benches. Lead curtains, lead bricks and concrete
blocks are sometimes used to shield radiation producing machines. Lead aprons may be used if it does
not significantly reduce the mobility and increase the radiation work time.
Practical radiation protection involves juggling the three factors to identify the most cost effective
solution.
8.2 ENGINEERING CONTROLS
The use of engineering controls is the most preferred method for reducing worker exposure to
radiation. Engineering controls are external accessories designed to protect the worker, or are built in
aspart of the design of the equipment or work area. The engineering controls should be designed and
built in to implement the time, distance and shielding principle. All engineering controls should
involve a plan for periodic inspection to determine the effectiveness of the protection provided.
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Radiation Producing Machines – Shielded enclosures and safety interlocks, are commonly used as
engineering controls for radiation producing machines. The radiation source is enclosed within a lead
lined radiation chamber, cabinet or in a concrete walled construction. Safety Interlocks are designed
to prevent access to the radiation hazard while it exists. Mechanical interlocks will prevent the
opening of a door accessing the source. For X-ray producing machines, electric or magnetic
Interlocks will trip to cut the power to the X- Ray source if a door is opened. The machines should be
designed to permit any lock out / tag out to prevent unauthorized use / accidents during servicing or
repair. Other design features include beam filtration or collimation and active devices such as audible
and visible warning signals. All these engineering controls of the machine should be respected and
should not be defeated.
Radioactive Materials - Fume hoods dedicated for using radioactive materials are most commonly
used as engineering controls. Any chemical or physical form which readily volatilizes or evaporates
into the air must be considered a potential airborne radioactivity risk. Use of volatile forms of
radionuclides, such as I-125 for iodination or H-3-Sodium Borohydride may generate airborne
radioactivity and should be used in a fume hood. Chemical reactions like labeling reaction for S-35
Methionine, generate S-35O2 gas and hence such reactions should be performed in a fume hood. Use
of radioactive materials in the millicurie amounts should always be used in a fumehood irrespective
of the volatility of the compound. Airborne radioactivity has resulted in unnecessary intakes and area
contamination in laboratories where the users were unaware of this risk and have not taken necessary
precautions.
Work areas should be designed in a way to facilitate easy removal of contamination without extensive
damage to the existing facility and surfaces. Epoxy coatings, laminates, floor coverings and protective
coatings shall be provided on bench surfaces and floors. Sinks shall be either plastic composite, or
coated with epoxy of the equivalent or manufactured of stainless steel, to aid in the decontamination
of surfaces. The area shall have readily available washing facilities suitable for decontamination
purposes.
8.3 ADMINISTRATIVE CONTROLS:
Administrative controls supplement the engineering controls and are put in place by the ILSC and
OSHE to limit external exposures as needed. OSHE’s efforts to maintain all radiation doses ALARA
form the foundation for all the administrative controls. These controls include compliance with
Radiation Safety Manual, procedures and directives. Licensing, Training, procurement control,
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routine contamination monitoring, postings and warning signs, worker exposure monitoring, and
medical surveillance form a part of the administrative controls.
8.4 PERSONAL PROTECTIVE EQUIPMENT
Personal protective equipment (PPE) should be worn whenever radiation work is performed at a
laboratory bench. The minimum personal protective equipment required is lab coat, safety glasses and
disposable gloves. PPE prevents or reduces the possibility of radioactive materials entering the body
via inhalation, ingestion or absorption through skin. All PPE should be routinely monitored for
contamination and contaminated PPE should be promptly disposed as radioactive waste. All PPE should
be routinely inspected to determine their integrity and any damaged PPE should be immediately replaced.
Laboratory coats and gloves shall be worn at all times when working with radioactive materials.
Double gloves shall be worn during radiosynthesis and iodination procedures and are strongly
recommended for all radioactive material handling. This will permit the changing of a contaminated
outer glove while still receiving protection from the inner glove. Individuals performing iodinations,
radio synthesis and labeling, may require additional protective coverings, such as plastic-lined
disposable coveralls and booties.
Protective Eye Wear is required in accordance with standard NUS requirements. This includes the use
of safety glasses with side shields or full-face shields as applicable. Protective Eye wear is strongly
recommended for individuals working with P-32 due to the large range of the 1.72 MeV beta. The
plastic lenses in safety glasses absorb one hundred percent (100%) of all alpha and beta particles
emitted by radioisotopes. This is important because live tissue on the exterior of the body (like eyes
etc.,) is most susceptible to radiation exposure Wearing safety glasses reduces alpha and beta particle
exposure to the eyes to zero.
Respiratory Protection may be necessary for certain radioisotope uses. However, respiratory
protection should only be used when engineering and other administrative controls and containment
do not provide enough protection. Respirators must be chosen carefully to ensure the proper fit and
type of cartridge, and the use must be monitored carefully. For this reason, use of respirators for
radioactive materials use must be pre-approved by the OSHE, documented and monitored. Prior to
using respirators for any reason, fit testing and medical monitoring are required. Only medically
qualified and trained personnel will be allowed to use respirators. Respirator training will be
conducted in accordance with Safety Department procedures.
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9 RADIATION LABORATORY SAFETY
9.1 GENERAL SAFETY GUIDELINES
When handling unsealed sources, adherence to the general laboratory safety rules as spelt out in the
General Laboratory Safety Manual, is required. In addition, the general radiation safety guidelines as
described below should be followed while working with sources of radiation.
Always read the safety data sheet of the radiochemical compound to determine the hazards
and implement sufficient controls to minimize hazards. Refer to Appendix F for generic
safety guidelines for working with commonly used radionuclides.
Always read the standard operating procedures or user manual of radiation producing
equipment and be aware of the controls to prevent any accidental exposure.
Do not eat, drink, smoke, chew gum, apply cosmetics or store such items in areas where
radioactive materials or radiation sources are used or stored. Food and beverage containers
may not be stored in the laboratory and refrigerators used for such purposes should be located
outside the laboratory
Always respect the safety interlocks and warning signs on radiation producing machines.
Tears/breaks in skin should be covered with waterproof tape to prevent accidental absorption
of radioactive material.
Open-toe footwear, sandals and flip-flops, and loose clothing or clothing that exposes body
areas are not allowed to be worn at any time in any laboratory.
Avoid contaminating objects such as telephones, light switches, water tap handles,
doorknobs, etc. Segregate items used with radioactive materials with those used with non-
radioactive materials to prevent cross contamination.
Hands should be washed thoroughly after using radioactive material, before going on breaks,
and at the end of the workday. Hands and legs should be thoroughly checked for
contamination after completion of radiation work.
Never pipette radioactive material by mouth.
Always wear radiation monitoring badges.
9.2 DESIGN AND SETUP OF RADIATION USE AREA
Requirements for work areas with unsealed sources are as follows:
Procedures involving radioactive material should be confined to smallest area possible. The
area should be as far as possible from any office locations. The work area should be
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adequately ventilated and also be as far away as possible from sinks and drains to prevent any
accidental spill entering the public sewers.
The work area should have clear warning signs indicating the use of radioactive materials. It is
advisable to use radiation in a room dedicated for such purpose. If radiation use is in a common
area, usage and storage area should have sufficient shielding to ensure that the dose rates are
below 0.5 µSv/hr at locations accessible by non radiation workers.
Work areas should be designed in a way to facilitate easy removal of contamination without
extensive damage to the existing facility and surfaces. Epoxy coatings, laminates, floor
coverings and protective coatings shall be provided on bench surfaces and floors. Sinks shall
be either plastic composite, or coated with epoxy of the equivalent or manufactured of
stainless steel, to aid in the decontamination of surfaces. The area shall have readily available
washing facilities suitable for decontamination purposes. Decontamination instructions and
supplies shall be readily available near the work area
All work involving unsealed radioactive material should be conducted on surfaces which
have been covered with polythene sheets that can be easily cleaned or with absorbent pads
that can be easily discarded as radioactive waste.
Suitable provisions should be provided for secured storage of radioactive materials in
freezers, cabinets etc.,
Adequate supply of shielding materials appropriate to the type of radiation being used should be
available.
Secondary containers must be used to prevent spillage and spread of contamination in the
event that the primary container fails to contain the radioactive material. Using drip trays
lined with absorbent material whenever possible.
A glove box or fume cupboard shall be provided for working with volatile or dry unsealed
sources. Significant activities of potential volatile radioactive material, e.g., unbound I-125,
unbound I-131, sodium iodide, sodium borohydride, tritiated water, etc., must be used in a
fume hood. (Refer to Chemical Safety Manual for the safe operation of fume hood)
Radioactive waste storage area should be located as close to the work area as possible to
prevent unnecessary transportation and related incidents. The disposable paper towels and foot
operated waste bins lined with removable red NUS radioactive waste bags should be readily
available.
Radiation monitors pertaining to the type of radiation should be readily available near the
work areas.
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10 PROCUREMENT AND RECEIPT OF RADIOACTIVE MATERIALS
10.1 RADIOACTIVE MATERIAL PROCUREMENT
Purchase of radioactive materials should be done ONLY by individuals who possess valid radiation
licenses. The license holder should order and use ONLY the radioactive materials that have been
listed in the license application. If the license holder wishes to order isotopes not listed in the license,
a license amendment (for inclusion of the isotope) should be submitted to regulators through FSHO.
10.2 RECEIPT OF RADIOACTIVE MATERIALS
The packages received at NUS typically fall under two categories
Excepted packages (Limited Quantity Packages) - packages with radioactivity amount less than one
thousandth of limits listed in Second Schedule Table 1 of Radiation Protection (Transport of
Radioactive Material) Regulations.
Type A packages - packages with radioactivity amount more than that of excepted packages but less
than the amount listed in Second Schedule Table 1 of Radiation Protection (Transport of Radioactive
Material) Regulations.
All radioactive material packages should be inspected to determine if
the material received is what was ordered. Verify that the label on each container agrees with
the description of the material specified in the packing slip and that the identity and activity
of the material are consistent with what was ordered.
the package appears to be undamaged. Check the integrity of the final source container
looking for a broken seal or a cracked vial or for evidence of loss of liquid, e.g., discoloration
of the packaging material.
the levels of contamination and external exposure rate on the external packaging material are
within acceptable limits The exposure levels should be below 5 µSv/hr for Excepted
packages and 2 mSv/hr for Type A packages. The removable contamination levels as
checked using a liquid scintillation counter should be less than 200 dpm per wipe area of 100
cm2 (dpm- decays per minute) If contaminated, dispose the outer packaging as radioactive
waste. If not contaminated, obliterate all radiation labels before discarding in the regular
trash.
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Appropriate PPE and radiation monitoring badges should be worn during package inspection. The
exposure levels should be determined by exposure rate meter and contamination levels should be
determined by a wipe test. Please refer to Section 17 on Contamination Monitoring and Section 18 on
External Exposure Monitoring for further details. All necessary precautions should be taken to
prevent spread of contamination and minimize exposure to all individuals including public during the
receipt and inspection of the package.
11 PROCUREMENT AND COMMISSIONING RADIATION PRODUCING MACHINES
Purchase of radiation producing machines should be done ONLY by individuals who possess
radiation licenses. The license holder should order and use ONLY the radiation producing machines
that has been listed in the license application. If the license holder wishes to use a radiation producing
machine not listed on the license, a license amendment (for inclusion of the new machine) should be
submitted to regulators through FSHO.
Before commissioning a radiation producing machines, an initial exposure rate survey should be
performed and documented on the Radiation Machine Inspection and Survey Form as shown in
Appendix H. The surveys should be performed when it is on and operating at full power. The form
should include a description and serial number of the equipment surveyed, a sketch or description of
the equipment surveyed, and an indication of the survey results. A record of the results shall be kept
for a period of three years. The exposure rates should be less than the values listed in rows six through
eleven in the Table 5 provided in Section 18.1.3.
12 INVENTORY OF RADIOACTIVE MATERIALS
All PI who has in his/her possession any radioactive material shall keep a record of the following
particulars in respect of the radioactive material.
a. Name and activity of the radioactive material at the date specified by the manufacturer;
b. Date of receipt;
c. Location of the radioactive material
d. For sealed sources:
i. The distinguishing number or other identifying mark; and
e. For unsealed sources:
i. Quantity used each time and the date and purpose of use; and
ii. Date and the manner of disposal
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The Laboratory Inventory form shown in Appendix I should be used to record the above information for
unsealed radioactive materials .If any radioactive material has been lost or mislaid, it shall be the duty of
the radiation worker to notify the PI and the FSHO of the loss or missing radioactive materials
immediately.
If the radioactive material is not accounted for within 24 hours, the PI shall notify RSO who will in turn
inform RPNSD, NEA.
13 TRANSFER OF RADIATION SOURCES
13.1 TRANSFER OF RADIOACTIVE MATERIALS
Radioactive materials can be transferred from one PI to another only after visual verification of the
receiver’s license to ensure that the receiver has permission to possess and use the particular
radioisotope. After the transfer, the laboratory inventory form should be updated accordingly with the
amount of radioactive material transferred, date of transfer and radiation license number of the
receiver. The transfer should be performed only by a licensed radiation worker with the permission of
the PI. There are different regulatory requirements based on whether or not motorized vehicles (cars,
trains, buses, scooters, bikes etc) are used to transfer the radioactive materials to the destination
location.
WITHOUT USING MOTORIZED VEHICLES
The material should be sufficiently shielded to ensure that the exposure rate outside the shielded
container is less than 40 µSv/hr at 5 cm. The container should have a label with the name and activity
of the radionuclide. While transporting the shielded container, the radiation worker should use the
path that is shortest and has least human traffic. The radiation worker should never leave the
radioactive material unattended in public area.
USING MOTORIZED VEHICLES (PERSONAL AND PUBLIC VEHICLES)
Please contact Radiation Safety Officer for help with transfer of radioactive materials using motorized
vehicles. In this case, the packaging, labeling, and activity amounts in the package should comply
with the Radiation Protection (Transport of Radiation Materials) Regulations. It will be a serious
violation of NEA rules if radioactive materials are transferred in motorized vehicles without
following the appropriate precautions. Please provide advance notice of such transfers to allow time
to verify the recipient’s license information and preparation of necessary shipping documents.
13.2 TRANSFER OF RADIATION PRODUCING MACHINES
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PI/equipment owner should notify the FSHO before any radiation producing machine is transferred to
another individual within NUS or sold to another individual outside NUS. If the machine is being
transferred or sold, the equipment owner should verify that the new owner possess the valid radiation
license prior to transferring/selling the equipment. The new PI/Equipment owner must obtain
necessary licenses and complete trainings prior to use of the equipment. The FSHO will notify the
RPNSD of the removal of the equipment and will cancel all licenses if necessary.
14 STORAGE OF RADIATION SOURCES
All sources of radiation (radioactive material and radiation producing machines) should be secured to
prevent unauthorized removal or access. Hall freezers, freezers in common rooms, etc., containing
radioactive material stock must be kept locked at all times to ensure that radioactive material is
secured against theft. It is advisable to lock the radioactive waste containers to ensure unauthorized
access. The exposure rates in radioactive material storage area should be less than the values listed in
rows one through four in the Table 5 provided in Section 18.1.3. The exposure rates in radiation
producing machine storage locations should be less than the values listed in rows six through eleven in
the Table 5 provided in Section 18.1.3.
All containers storing liquid radioactive materials should be placed in secondary containers with
adequate size to retain the leak of entire contents from the primary container
15 RADIATION POSTINGS AND WARNINGS
The purpose of posting and labeling is to identify and communicate
the potential or actual presence of radiation levels in excess of specified limits.
areas, containers, or equipment which require special controls
Labels and signs with radiation symbol shall not be used for any purpose other than radiological
control as described below or as specified by the RSO. Labels and notices to be used or displayed shall
be as large as practicable. When any radiation hazard ceases to exist, all labels and notices used or
displayed in connection with such hazard shall be removed immediately.
For all irradiating apparatus generating X- rays and Particle Accelerators a standard radiation hazard
symbol (please refer to Appendix J) should be placed on the apparatus. The words “DANGER –
RADIATION. This apparatus produces radiation when energised” should be placed immediately
adjacent to the symbol.
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For all irradiating apparatus with sealed radioactive material and containers containing unsealed
radioactive material the standard radiation hazard symbol specified in Appendix J should be placed on
the apparatus/container. The words “DANGER – RADIOACTIVE” and the name and activity (with
reference date) of radionuclide should be immediately adjacent to the symbol. Small containers like
eppendorf tubes containing less than 1 µcurie of activity need not be individually labeled as long as
they are stored in a labeled secondary container or rack. Labeling laboratory containers is not required
as long as -
the containers hold materials during transient procedures lasting only a few hours AND
that are disposed of immediately upon the completion of an experiment AND
under the control of or in the presence of a licensed user
All equipment such as incubators, freezers, gel dryers, glassware, etc., that will handle radioactive
material should have standard radiation hazard symbol (please refer to Appendix J) posted on the
equipment.
All entrances to rooms and labs containing radioactive material or irradiating apparatus should have
standard radiation hazard symbol (please refer to Appendix J) posted on the doors.
The radiation work area should have standard radiation hazard symbol posted at the work area to clearly
warn individuals about the use of radioactive materials
16 RADIATION INSTRUMENTATION
All users of different sources of radiation must have a survey meter which is sensitive to (i.e., is able
to detect) the type and energy of radiation being used.
There are two factors that decide the type of radiation detector that a user should choose
Type of radiation to be monitored – alpha, beta, gamma orlow energy x rays
Purpose – Contamination monitoring (with units of counts per minutes - CPM) or Exposure
monitoring (with units of Roentgen/hr or Sievert/hr).
For contamination monitoring, Pancake Geiger Mueller, End Window Geiger Mueller, Solid Sodium
Iodide Scintillation detector are the most commonly used detectors in research laboratories.
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For exposure monitoring, Energy compensated Geiger Mueller or Ionization chamber should be used.
It may be possible to use the contamination monitoring detectors for exposure monitoring if
calibrated appropriately. However, Energy compensated Geiger Mueller and Ionization chamber
detectors are the ideal choice for exposure monitoring due to several advantages.
Table 2 can be used as a guide to select the correct type of radiation detector. Please note that the
following table only shows the commonly used purpose of each detector and also the type of radiation
that is detected most efficiently by each detector.
Table 2: Summary of Use Characteristics of Various Meters
Type of Detector Sub type Type of radiation Purpose
GM
pancake beta contamination
end window beta contamination
energy compensated beta and gamma exposure rate
Scintillation
Solid gamma, low energy x rays contamination
Plastic beta contamination
liquid scintillation beta contamination
Ionization chamber NA gamma exposure rate
17 CONTAMINATION MONITORING
Periodic contamination checks are required in areas where unsealed sources are used to prevent
spread of contamination.
Removable contamination can be readily removed using proper decontamination procedures. Removable
contamination in any amount may present both an external and internal hazard because it can picked up
on skin and possibly ingested.
Fixed contamination cannot be readily decontaminated. Fixed contamination generally does not present a
significant hazard unless the material comes loose or is present in such large amounts that it presents an
external radiation hazard.
Total Contamination is the term used to refer to the presence of both removable and fixed
contamination.
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17.1 CONTAMINATION SURVEYS
Routine Surveys – Routine contamination checks should be performed for personnel contamination
and suspected laboratory contamination before, during or after use of radioactive materials. Monitor
work area, hands, shoes, and clothing for contamination after each procedure and before leaving area.
This survey need not be documented and the contaminated areas should be cleaned immediately.
Please refer to Section 17.4 for decontamination procedures.
Periodic Surveys – Contamination checks of labs should be performed and documented at scheduled
intervals and frequency determined by laboratory classification as shown below
Area of Use Documented Survey Frequency
Routine laboratory (open containers) Monthly
Equipment use room (no open containers) Quarterly
Waste storage room Monthly
Iodination rooms After each use
If no radiation work was performed in labs and PI possesses no radioactive materials, then surveys are
not required. However, the survey documentation should indicate that surveys were not performed for
the time period. The PIs sharing the common areas should identify radiation worker and assign the
responsibility of performing the surveys.
Table 3 summarizes the commonly used means of contamination monitoring for radionuclides
commonly used in research laboratories. Information on the purchase of radiation detectors can be
obtained from the radiation safety officer x 66961
Table 3: Summary of Efficiencies of Various Detectors to Commonly Used Radionuclides
Radionuclide Pancake GM
Efficiency
End Window
GM Efficiency
LSC
Efficiency
NaI detector Efficiency
Thin Crystal - (2mm x 1 in)
Thick Crystal - (1 in x 1 in) 3H Not Detectable Not Detectable 40% NA
14C 10% 5% 85% NA
35S 10% 5% 85% NA
32P 50% 30% 95% NA
33P 15% 7% 85% NA
I-125 <1% <1% 80% 30% (thin)
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Cr-51 <1% <1% 30% 2% (thick)
I-131 18% 9% 90% 15% (thick)
Co-57 <1% <1% 80% 8% (thick)
Liquid scintillation detectors are used to check removable contamination from any surface by the
means of wipe tests. All other detectors can be used to determine removable, fixed or total
contamination on a surface depending on how the survey is performed and also on the energy and
type of radiation emitted by the radionuclide. All the detectors except the liquid scintillation detector
are small and portable.
PANCAKE AND END WINDOW GM DETECTORS
These detectors are small and portable and used for evaluating total contamination of beta emitting
radionuclide. GM detectors are not recommended for measuring gamma contamination in the
laboratory. Please note that H-3 is not detected by this detector since they do not have enough energy
to penetrate the window. The detection efficiencies for various beta emitting nuclides are given
below. Pancake detectors have about twice the counting efficiency for beta emitters than end-window
detectors.
SCINTILLATION DETECTORS
A scintillator is a material which gives off a photon (flash) of light when struck by radiation. Sodium
Iodide (NaI) solid crystal, plastic and liquid scintillation detectors are the common types of
scintillation detectors used for contamination monitoring in research laboratories. While NaI solid
crystal and plastic scintillators are used for measuring both fixed and removable contamination, the
liquid scintillation counters are used only for measuring removable contamination.
17.1.2.1 SODIUM IODIDE SOLID CRYSTAL
NaI scintillator is the most commonly used solid crystal scintillation detector. Thin crystal (1 inch x 2
mm) NaI detectors are used for low energy gamma of energy range 10 keV to 60 keV. This detector
is commonly used for nuclides like I-125.Thick crystal (1 inch x 1 inch) NaI detectors are used for
higher energy gamma emitting nuclides like Cr-51, I-131, Co-57 etc.,
17.1.2.2 PLASTIC
They are not very commonly used. They are ideally used for beta contamination monitoring. GM
detectors are cheaper and provide comparable performance for beta detection.
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17.1.2.3 LIQUID SCINTILLATION
Liquid scintillation counting is a method of counting a radioactive sample by dissolving it in a
mixture of chemicals called scintillation fluid or cocktail. The cocktail emits light when beta particles
lose energy. The light flashes directly relate to the amount of contamination in the sample. They are
ideal for counting radionuclides that decay by alpha and beta particle emission (H-3, C-14, P-32, S-
35) and are also used to measure some low energy gamma emitters (I-125) which emit auger
electrons as part of their decay. The efficiency of the detection is reduced by several factors that
interfere during the process of generation and transfer of light photons. (This reduction in efficiency
is termed as quenching). The detection efficiencies of commonly used radioisotopes are given below
in Table 4 (Assuming 50% quenching)
Table 4: LSC Detection Efficiencies of Commonly Used Radionuclides
Radionuclide LSC Efficiency
3H 40%
14C 85%
35S 85%
32P 95%
33P 85%
I-125 80%
17.2 HOW TO PERFORM A CONTAMINATION SURVEY
For guidelines on how to use a portable radiation detector for measuring contamination refer to
Appendix K. Guidelines on how to use a liquid scintillation counter for removable contamination
monitoring, please refer to the Appendix L
Prior to performing any survey, radiation monitoring badges and appropriate PPE should be worn. Care
should be given to prevent the possibility of personal contamination or cross-contamination during
surveys.
Monitoring and periodic checks shall be conducted on the most common sites for contamination, such as
survey meter handle, soap/towel dispensers, drawer handles, refrigerator/freezer handles, chair edges,
writing utensils, survey record books, floors, radio dials, telephone receiver/keypad, µwave oven touch
pads/handles, doorknobs, light switches, non-radioactive trash containers etc., All designated "break
rooms" and “wash sinks” must be surveyed. All areas where radioisotopes are used, stored or
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disposed, and the floors adjacent to those areas must be surveyed. This includes centrifuges,
incubators, cold rooms, sealing equipment, pipettes and any other equipment which has been used for
radioisotope work. Areas of the lab that would not be expected to become contaminated, such as
desks, telephones, door knobs, light switches, etc, should also be randomly surveyed to assure that
contamination has not occurred. It is a good practice to rotate the non-radioactive areas tested so the
whole laboratory will be monitored over time and problem areas can be identified and
decontaminated.
The surveys should be documented in the Laboratory Contamination Survey Form shown in
Appendix M. The form should include a sketch or description of the areas surveyed, and an
indication of the results.. If a liquid scintillation counter is used for contamination checks the LSC
print out may be attached to the Laboratory Contamination survey form. A record of the results shall
be kept for a period of three years. All contaminated items shall be either decontaminated or discarded as
radioactive waste if decontamination is not feasible.
17.3 CONTAMINATION ACTION LEVELS
Following guideline should be used to judge whether an area is contaminated and if needs
decontamination.
For portable contamination monitors reading in CPM (end window GM, Pancake GM and solid
scintillation detectors) the surface is considered contaminated if the reading on the meter in CPM is two
times greater than the background count rate.
For liquid scintillation counter, the surface is considered contaminated if the reading on the printout from
the LSC is greater than 200 DPM/wipe assuming a wipe area of 100 cm2. Alternatively, the permissible
limits as specified under Fifth Schedule of the Radiation Protection (Ionising Radiation) Regulations (see
Appendix D), can also be used.
If contamination is found, record the result and indicate the action taken on the Laboratory
Contamination Survey Form. Such locations should be immediately decontaminated and a record of
the survey taken after decontamination should also be documented. Please refer to the Section 17.4 on
decontamination procedures on how to remove contamination. A repeat survey of the location must
then be made after decontamination and should be recorded to verify that the removable
contamination level is less than the limits mentioned above. All contamination should be reduced to a
level as close to background as is reasonably achievable. Please contact Radiation Safety Officer if
you are unable to reduce your contamination to the levels listed here.
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17.4 DECONTAMINATION PROCEDURES
Decontamination shall be conducted to remove loose or fixed surface radioactivity when surveys
revealed the presence of radioactive contamination. At the end of the experiment, it is the responsibility
of all users to decontaminate the work area prior to leaving the work area. General methods of
decontamination are given in the following sub-sections.
DECONTAMINATION OF SKIN
Use proper contamination survey meter for the isotope used and determine readings and area of
contamination. Wash affected area with lukewarm water. Cold water will constrict pores making it
difficult to remove contamination. Hot water may expand pores causing further penetration through the
skin surface. Re-survey after wash and note readings. Continue to wash and survey until no more
contamination is detected or if skin starts to become irritated. Do not scrub with anything rough or harsh.
DECONTAMINATION OF CLOTHING
Remove contaminated items immediately. Decontaminate skin if affected. Place all clothing items in a
bag and label as required for radioactive waste.
DECONTAMINATION OF EYES
Immediately flush eye with water.
DECONTAMINATION OF LAB FLOOR AND BENCHES
Restrict access. Monitor and define boundaries. Clean up contaminant using absorbent paper wiping from
outer edge inwards. Repeat the process several times and use a monitor to check the progress of the work
until background levels are detected. Place all absorbent paper in a bag and label as required for
radioactive waste.
18 EXTERNAL EXPOSURE MONITORING
External exposure monitoring can be performed by using appropriate portable radiation detectors or by
using radiation monitoring badges. The portable radiation detectors provided a live reading of the
surrounding exposure levels. Radiation monitoring badges provide cumulated data of an individuals
exposure over a period of time while working with radiation.
18.1 AREA EXPOSURE MONITORING
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Exposure rate is usually measured in units of Roentgen/hour (R/hr) that represents the amount of
ionization created in air by X rays or gamma rays. The dose rate to a human is usually measured in
units of Sieverts/hour (Sv/hr) and it represents the amount of radiation dose an individual has
received. The exposure rate and dose rate are interchangeably used in the industry, with the
following conversion factor. 1 Sv/hr ~ 0.01 R/hr.
Exposure monitoring can be performed by using either an energy compensated GM probe or by using
an Ionization chamber. Although pancake GM and scintillation detectors can be calibrated to measure
exposure, it is not advisable to use them for exposure monitoring because of over estimation of
exposure rates in the 20 keV to 160 keV range as they are usually calibrated at a higher energy using
Cs-137 (662 keV gamma ray)
ENERGY COMPENSATED GM DETECTORS
These are special type of GM detectors that are designed to compensate for overestimation of
exposure rates at low energy. These detectors usually have a window that can be opened to detect
beta radiation. This detector cannot be used for measuring exposure from very low energy X rays
(<50 keV).
IONIZATION CHAMBERS
Ionization chambers are commonly used in areas where large exposure rates are anticipated (nuclear
plants, radiopharmacy, teletherapy machines etc.,) They can also be designed to detect both beta and
gamma radiation.
EXPOSURE RATE SURVEYS
Periodic exposure rate checks are required in areas where sealed and unsealed sources are stored and
also where radiation producing equipments are used. Routine exposure rate checks should be
performed to ensure the limits shown in Table 5 are not exceeded.
Table 5: Regulatory Exposure Rate Limits for Various Radiation Use Conditions
Number Area Dose Rate Location
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1 Radioactive material storage
area/room 0.5 µSv/hr
Public/non
radiation worker
access locations
2 Radioactive material storage
area/room 4 µSv/hr
radiation worker
access locations
@ 1 m from the
storage location
3 Radioactive material storage
area/room 40 µSv/hr
radiation worker
access locations
@ 5 cm from the
storage location
4 Radioactive material waste
storage area 0.5 µSv/hr
Public/non
radiation worker
access locations
5 Radioactive material waste bag 1 µSv/hr Outside the bag
6 Equipment with sealed source
while not in use 1.5 µSv/hr
outside the
equipment @
public/non
radiation worker
access locations
7 Equipment with sealed source
while in use 10 µSv/hr
outside the
equipment @
public/non
radiation worker
access locations
8 Veterinary diagnostic
equipment, while in use at
maximum current
10 µSv/hr
Public/non
radiation worker
access locations
9 Veterinary diagnostic
equipment, while in use at
maximum current
1 milliSv/hr one meter from
the machine
10 X-Ray machines and
Accelerators while in use 10 µSv/hr
radiation worker
access locations
11 X- Ray machines and
Accelerators while in use 1.5 µSv/hr
Public/non
radiation worker
access locations
Exposure rate surveys should be conducted prior to commissioning of radiation producing equipment
and should be documented. Also, annual exposure rate surveys should be performed and documented
for radiation producing equipment.
HOW TO PERFORM A SURVEY
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For guidelines on how to use a portable radiation detector for monitoring radiation exposure please refer
to Appendix K. Radiation monitoring badges also should be worn while performing surveys. Exposure
rate monitoring should be performed at locations specified in the Table 5 in Section 18.1.3 using either
an energy compensated GM probe or an ionization chamber. For radiation producing equipments, the
surveys should be performed when it is on and operating at full power. The initial surveys performed
prior to commissioning of radiation equipments and subsequent annual surveys should be
documented in the Radiation Machine Inspection and Survey Form shown in Appendix H. The form
should include a description and serial number of the equipment surveyed, a sketch or description of
the equipment surveyed, and an indication of the survey results. A record of the results shall be kept
for a period of three years.
18.2 PERSONNEL EXPOSURE MONITORING
The purpose of personal dosimeters is to record the radiation dose received by the radiation worker in the
course of his work. Personal dosimeters also known as Thermo luminescent Dosimeters (TLDs) are later
analyzed to determine the recorded dose. In research labs, personal exposure monitoring consists of using
a whole body badge to record the whole body dose and using a ring badge to record the dose to fingers.
The dosimeters are usually provided by RPNSD upon approval of the L5, L6 and R1 license applications.
The badges will be shipped to the FSHO, who will then forward it to the individual workers. The badges
are exchanged on a monthly basis. The new badges are sent to the FSHO, who will co-ordinate the badge
exchange and shipping to RPNSD for analysis. It is necessary the users follow the prescribed badge
exchange frequency for accurate record of the radiation dose they received. The dose analysis reports are
sent to the FSHO who will notify the user.
If you are a radiation worker and have been issued a TLD to monitor your radiation exposure, you
should follow a few simple practices to ensure that the dosimeter accurately records your radiation
exposure.
TLD badges will not be able to record dose from use of H-3 as the beta radiation emitted by
H-3 does not have sufficient energy to penetrate the badge.
Wear only your own TLD, never wear another person's badge.
Wear whole body badges between the collar and waist with the shiny surface facing outside
To avoid contamination, wear ring badges underneath gloves with the chip on the palm side
of the hand that handles radiation sources.
Do not store your badge near radiation or high-heat sources.
Do not leave your badge attached to your lab coat (when not wearing your lab coat).
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Care must be taken not to cross-contaminate a badge or ring dosimeter. A contaminated
dosimeter will give a false-positive dose reading since it continues to be irradiated even after
work is completed. If you suspect contamination on your badge, notify the Radiation safety
officer immediately.
Lost badges should be immediately notified to the Radiation Safety Officer
Never intentionally expose your badge to any radiation.
Do not wear your badge when receiving medical radiation exposure (e.g., x-rays, nuclear
medicine, etc.).
Return your badge to your FSHO for processing at the end of the wearing period.
Where any individual ceases to be employed as a radiation worker, OSHE shall provide a record of
radiation dose received while working at NUS. FSHO/RSO should complete the Transfer Record
Form show in Appendix N and send a copy to the radiation worker and also to the Chief Executive.
19 INTERNAL EXPOSURE MONITORING
Certain individuals who handle unsealed radioactive materials in relatively large quantities are
monitored by OSHE for internal contamination by perfroming bioassays. The bioassays are of two
distinct types –
19.1 THYROID MONITORING
The thyroid gland accumulates 20 - 30% of the soluble radioiodine taken in by the body and hence
routine thyroid monitoring for individuals using radioiodine is necessary. Following individuals
should notify the Radiation Safety Officer before performing single experiment involving use of
more than 1 mCi of free, unbound radioactive isotopes of Iodine (I-125, I-131 etc.,) and
Sodium Iodide and Potassium Iodide.
more than 10 mci of radioactive isotopes of Iodine (I-125, I-131 etc.,) bound to molecules.
Such individuals will be subjected to a baseline Thyroid monitoring test to determine the baseline
thyroid burden. Later, thyroid monitoring should be performed after 24 hours but within one week of
actual use of radioiodine. The radioiodine activity in the thyroid will be measured and compared to
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the baseline value to determine if the body burden is within ALARA levels shown in Table 1
provided in Section 7.2.
19.2 URINE ANALYSIS
Individuals working with more than 10 mCi of tritium at any one time should contact Radiation
Safety Officer within 24 hours. The urine samples will be collected and analyzed using liquid
scintillation counter to determine if the body burden is within the ALARA levels shown in Table 1
provided in Section 7.2.
20 DISPOSAL OF RADIOACTIVE WASTE
Radioactive waste refers to wastes containing radio isotopes, and may be potentially detrimental to
human health and/or the environment, and which requires special treatment and disposal. Radioactive
wastes generated in the laboratories in NUS must be tested and disposed in a safe and environmentally
sound manner. RSO will co-ordinate with the users, RPNSD and waste disposal site disposal 3 to 4 times
per year for collection and disposal of radioactive waste from labs.
20.1 GENERAL REQUIREMENTS
All radioactive waste should be in the dry form for regulators to accept the waste for disposal. So all
liquid (solvent and aqueous) waste generation should be minimized and should be absorbed in a
chemically compatible absorbent before waste pick up.
For liquids generated during rinsing of containers containing radioactive material, the first (1st) and
second (2nd) rinsing should be collected in containers and absorbed in chemically compatible absorbent
before waste pick up. Rinse water from third (3rd) and subsequent rinsing of apparatus may be discharged
into the sewer directly at point of use.
Aqueous and solvent type radioactive wastes should not be mixed in the same container. Whenever
possible each container should contain waste only contaminated with a single radionuclide.
Glassware and sharps such as vials and syringes are to be packed separately in bins or multiple layers of
bags suitably padded before they are placed in radioactive waste bags.
For Animal carcasses, the means of disposal will depend s on the activity of the nuclide per gram of the
carcass. Please refer to Section 20.3 for more information on disposal requirements of animal carcasses.
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Sealed radioactive materials cannot be disposed in Singapore. All sealed radioactive materials should be
either returned back to the vendor or should be stored in a secluded storage area permanently. Inform
FSHO of any sealed source that you wish to discard.
For radiation producing machines, no disposal of any irradiating apparatus is allowed, without the
prior approval in writing to OSHE and RPNSD.
No compaction of radioactive waste is permitted.
20.2 STORAGE AND HANDLING REQUIREMENTS
Proper gloves are to be worn by all while handling the radioactive wastes to prevent spread of
contamination.
The PIs shall ensure that all radioactive wastes are segregated and stored at a designated storage area,
marked clearly with warning signs. The waste storage locations are to be confirmed with the assistance of
FSHO. General waste and recyclable materials shall not be stored in this radioactive designated storage
area.
Radioactive waste materials must be secured at all times. This may be accomplished either by
maintaining materials in a designated locked freezer or cabinet or by restricting access to the room in
which the materials are stored.
Radioactive waste should be stored in shielded containers to ensure that the dose rates outside the
container are less than 0.5 µSv/hour. The selection of shielded containers should be based on the type of
radiation emitted by the radionuclide. (plastic containers for beta emitter and leaded containers for
gamma emitters)
All dry solid radioactive wastes must be deposited into red plastic waste disposal bags with NUS logo
and radioactivity hazard symbol. (These bags are available from OSHE.)
Each bag when full shall be closed and securely sealed with red masking tape.
The activity, content and isotope shall be entered on both the i) “Request for Disposal of Radioactive
Waste Form” (OSHE/F/RS/01, Please refer to Appendix O) which is available on the website
http://www.nus.edu.sg/osh/forms.htm and ii) on the radioactive waste container label (see Appendix P).
The radioactive waste container label is supplied by OSHE upon request and it is to be adhered onto the
waste disposal bag. They are to be checked by the OSHE and/or the Faculty Safety & Health Officers
before they are certified safe for disposal.
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Competent person shall ensure good housekeeping for all waste stored in the common area under their
jurisdiction.
20.3 WASTE DISPOSAL REQUIREMENTS
OSHE shall coordinate with users, RPNSD, and waste disposal site for the safe disposal of radioactive
wastes.
For dry waste, the amount of radioactivity in each waste bag should be less than the radionuclide’s
corresponding exemption limit for that nuclide as listed in Appendix B. Each disposal bag should
contain waste only contaminated with a single radionuclide. The exposure rate on the surface of each bag
must NOT be greater than 0.1 mrem/hr or 1 µSv/hr. OSHE shall measure the levels of each radioactive
waste bag as a second level of inspection and audit.
For Animal carcasses, if the activity per gram of the carcass is below the radionuclide’s corresponding
exemption limit for that nuclide as listed in Appendix B, it can be sent for incineration. The exposure
rate on the surface of each bag must NOT be greater than 0.1mRem/hr or 1 µSv/hr before sending for
incineration. For Animal carcasses, if the activity per gram of the carcass is above the radionuclide’s
corresponding exemption limit for that nuclide as listed in Appendix B, the user should store in a
dedicated freezer and
a. decay until activity is below the exemption levels (for short lived nuclides eg., P-32, P-33, I-
125, S-35)or
b. contact OSHE for disposal (for long lived nuclides eg., C-14, H-3
21 ACCIDENT / INCIDENT REPORTING AND INVESTIGATION
21.1 RADIATION ACCIDENTS
Under the Radiation Protection (Ionising Radiation) Regulations 2001, a radiation accident shall be
considered to have occurred if:
a) An unexpected, uncontrolled high level of ionising radiation occurs as in the case of loss, by
damage of the radiation shielding, of a sealed radioactive source or of irradiating apparatus;
b) An individual enters a high radiation field by accident;
c) There is loss of control of unsealed radioactive material causing a spillage or leakage of the
radioactive material;
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d) The skin or clothing of an individual becomes contaminated; or
e) Radioactive material is accidentally released into the environment in excess of the discharge
level permitted by the Regulations;
such that:-
i. Any individual has, or could have, received an effective dose which is equal to or in excess of
one fifth of the dose limit as specified in the Second Schedule (see Appendix A);
ii. The skin or personal clothing of any radiation worker is contaminated in excess of 50 times (2.5
times for any other individual) the appropriate permitted contamination limits for skin or personal
clothing as specified in the Fifth Schedule (see Appendix D);
iii. Any area in the premises where work with ionising radiation or radioactive material is conducted
is contaminated in excess of 50 times the permitted contamination limit for surfaces in such an area as
specified in the Fifth Schedule (see Appendix D); or
iv. Any other area is contaminated in excess of 10 times the permitted contamination limit for
surfaces in low level laboratories as specified in the Fifth Schedule (see Appendix D).
In addition to the above, if any radioactive material has been lost or mislaid, it shall be the duty of the
radiation worker to notify the PI/ Licencee of the loss or missing radioactive materials immediately. If the
radioactive material is not accounted for within 24 hours, the licensee shall notify OSHE who shall in
turn inform RPNSD.
21.2 ACCIDENT RESPONSE PROCEDURES
All accidents, known exposures and near misses (which does not result in injury) MUST be reported to
OSHE via the online Accident/ Incident Reporting System (AIRS)
http://nus.edu.sg/osh/services/airs.htm. All injuries requiring first aid treatment shall be recorded in the
First Aid Log Book.
Reporting must be done within twenty-four (24) hours. It can be submitted by the informant, injured
staff/ student, PI, Laboratory Supervisor or other representative if the staff/ student are unfit or unable to
do the initial report.
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All accidents and incidents must be investigated by NUS in order to identify the root cause(s) and
contributing factor(s). The investigation team will be headed by Radiation Safety Officer and may
comprise of representatives from OSHE, the Departmental Safety and Health Committee, the Faculty
Safety & Health Officer, PI, Laboratory Supervisor or other members if required.
Pending the investigation results to confirm whether an excessive exposure has indeed occurred, the RSO
shall:
i. Immediately suspend the radiation worker from work in which he will be exposed to radiation.
ii. Arrange for medical examination for the radiation worker and affected personnel
iii. Obtain the contact details of the affected personnel (which may be a visitor, contractor, or a
member of public).
Where the investigation confirms that there is indeed an excessive exposure, OSHE shall be responsible
to notify the Chief Executive of RPNSD.
For more information, refer to the SOP ‘Accident / Incident Reporting and Investigation’
(OSHE/SOP/GL/02) available in the website http://www.nus.edu.sg/osh/sop.htm.
22 RADIATION EMERGENCIES
An incident which involves serious injury or death, fire, explosion, or significant release of a health or
life threatening material, coupled with a radiological accident as defined in Section 21 of this manual,
treatment of injured individuals takes precendece over confining release of radioactivity.
Emergency phone numbers and safety personnel contacts are provided in Section 27 of this manual
23 RADIOACTIVE MATERIAL SPILL RESPONSE
For laboratories using unsealed sources, the PI/ Lab Supervisor shall ensure that the following
equipments are provided:
a. Spill packs containing a plastic bag containing gloves, overshoes, absorbent material (paper
towels, vermiculite, etc), trays, thongs, etc.
b. Suitable radiation counters to monitor contamination levels.
Spills involving radioactive material can be classified as Minor or Major. Spills in the microCurie
amounts in a single lab are considered minor spills. Spills in the milliCurie amounts in a single lab or
Page | 48
spill in microCurie amounts over a large area including corridors and stairs are considered major spills.
23.1 MINOR SPILLS
Notify all persons in the room about the spill immediately. Monitor personnel before they leave and
then change clothes or laboratory coats, as necessary.
Using an appropriate contamination monitor (GM or Scintillation counters) survey all suspected
laboratory personnel (including yourself) who might be contaminated. Follow decontamination
procedures (see Section 17.4) before they leave the room. Survey the spill area and mark or cordon off
the spill area.
Confine the spill immediately by dropping absorbent paper on the liquid spill; if the spilled material is
dry, dampen it to prevent the radioactive particles from dispersing.
Wear double gloves, laboratory coats, shoe covers, appropriate dosimetry, and other protective
equipment as needed.
Clean up all spills using absorbent paper. Use a liquid cleaner spray and clean the spill area. Repeat the
process several times and use a monitor to check the progress of the work. Repeat a contamination survey
to ensure the contamination levels are three times below background. All radioactive materials (including
absorbents, etc) should be disposed as radioactive wastes.
Notify the PI and FSHO of the spill. Report the spill to OSHE via the online Accident/ Incident
Reporting System (AIRS) http://nus.edu.sg/osh/services/airs.htm
23.2 MAJOR SPILLS
Take note of the nature of the spilled material in order to advise emergency personnel on the possible
hazards of the spill.
Notify all persons not involved in the spill cleanup to vacate the room at once and prohibit entrance
except to emergency personnel. Declare area off limits. Post warning signs at all its entrances. All
windows should be closed; fans and air conditioners should be switched off.
Contact the PI, FSHO and RSO immediately. The RSO will decide if clean up can be performed in house
or outside help needs to be called in.
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Any person who has accidentally inhaled, ingested or absorbed radioactive materials from the spill or the
spill cleanup process should immediately seek medical attention. Use a contamination monitor to check
and decontaminate affected personnel. Please refer to Section 17.4 for details on decontamination
procedures. If the spill has contaminated the clothing, discard the clothing at once. Discarded clothing is
to be disposed as radioactive waste.
Monitor the contamination levels of all persons involved in the spill clean-up by using the GM/
scintillation counters. .
All radioactive materials (including absorbents, etc) should be disposed as radioactive wastes.
Report the spill to OSHE via the online Accident/ Incident Reporting System (AIRS)
http://nus.edu.sg/osh/services/airs.htm
24 CHECKING OF LEAKAGE/ BREAKAGE OF SEALED SOURCE
All sealed sources should be checked for leakage by the owner of the sealed source at least once every 12
months. A register of the wipe tests conducted should be maintained. The procedure for performing leak
test is provided in Appendix Q. The source is considered leaking if the count rates from the wipe test are
above three times background count rate.
Where any radioactive substance is leaking, or is likely to leak:
a. RSO shall be informed immediately and OSHE will in turn notify RPNSD
b. immediate vacation of all appropriate areas to safeguard every individual present in the vicinity
of the sealed source
c. a leak-proof container shall be used to contain the leak until completely repaired.
d. decontamination carried out by properly equipped individuals supervised by the licensee or
qualified individual.
25 DECOMMISSIONING
25.1 DECOMMISSIONING OF LABS USING RADIOACTIVE MATERIAL
A radiation use location is said to be “decommissioned” only after
All radioactive material inventory balance are accounted for
Radioactive sources and irradiating equipment have been disposed off or transferred to
another laboratory
Wipe, survey tests have been conducted
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Upon completion of these steps, the FSHO completes the Laboratory Decommissioning Checklist and
files the confirmation documentation. FSHO will co-ordinate all license cancellations
25.2 DECOMMISSIONING OF RADIATION PRODUCING MACHINES
A radiation producing machine is said to be “decommissioned” only after
Source of the radiation is removed from the equipment using sealed radioactive materials
OR
Source of the radiation is completely impaired from the equipment using X ray tubes. The
tubes should be impaired in a manner that it will be impossible to use the tube again in the
future. Contact Radiation Safety Officer for further questions.
OR
The equipment is sent back to the manufacturer or supplying vendor for reuse or recycling.
OR
The equipment is sold to an individual outside NUS campus. (The equipment owner should
verify that the new owner possess any required license prior to selling the equipment)
The FSHO should be notified prior to the decommissioning of the equipment. FSHO will co-ordinate
all license cancellations
25.3 DECOMMISSIONING OF EQUIPMENT USING RADIOACTIVE MATERIAL
This applies to all equipment, instruments, refrigerators, freezers, lab ware or other apparatus where
radioactive material was used or stored. Before such equipment are given over for disposal,
transferred to another location,
they should be checked for contamination using the appropriate contamination monitor. If
radiation levels are found more than three times background levels, they should be
cleaned/decontaminated.
radiation labels found on the equipment is removed and/or defaced
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The surveys should be recorded on the Contamination Survey Form found in Appendix L. The
details of the equipment including name and serial number should be recorded on this form. All
equipment decommissioning records should be maintained by the PI. The FSHO should be notified
prior to the decommissioning of the equipment.
26 RADIATION LABORATORY INSPECTIONS:
Inspections of laboratories using radioactive materials and radiation producing machines will be done
the Radiation Safety Officer once every six months to verify compliance with Radiation protection
regulations. The Inspection will be performed against the Radiation Laboratory Inspection Checklist
provided in the Appendix S. The inspection will also include random measurements of exposure
levels and contamination levels in radiation use laboratories.
The inspection report along with the results of the inspection will be forwarded to the principal
investigator, and a recheck may be conducted in the event problems have been detected that need
corrective action.
27 EMERGENCY PHONE NUMBERS AND SAFETY PERSONNEL
CONTACTS
27.1 EMERGENCY PHONE NUMBERS
SCDF - Ambulance/Fire 995
Police 999
Campus Security (24hrs) x 1616 (6874 1616)
General Maintenance/ Breakdown of Services (24 hrs) x 1515 (6516 1515)
In the event of emergency, please call Campus Security and SCDF or Police
27.2 UNIVERSITY HEALTH CENTRE (UHC)
(http://www.nus.edu.sg/uhc/)
Main Clinic Satellite Clinic
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Kent Ridge Campus
20 Lower Kent Ridge Road
University Health Centre, Level 1
Bukit Timah Campus
469G Bukit Timah Road
Block B, #02-01, Multipurpose Auditorium
Operating Hours
Operating Hours
Mon – Thurs 8.30am – 6pm Mon/ Wed/ Fri 8.30 – 10.30am
Fri 8.30am – 5.30pm (during term only)
Closed on Sat, Sun & Public Holidays Closed on Tue, Thu, Sat, Sun &
Public Holidays
Closed for lunch from 12.30pm – 1.30pm
Last registrations are 15 mins before
closing time
Last registrations are 15 mins before
closing time
General Enquiries: 6601 5035
General Enquiries: 6467 5492
27.3 NEAREST HOSPITAL
In the event of critical injury/ illness after office hours, proceed to the Accident & Emergency Unit of a
nearby hospital. The nearest hospital in the vicinity of the University is:
National University Hospital (NUH)
Lower Kent Ridge Road
Singapore 119074
Main Line (24hr general enquiries) Tel: (65) 6779 5555
Emergency Tel: (65) 6772 5000
www.nuh.com.sg
27.4 OFFICE OF SAFETY, HEALTH AND ENVIRONMENT (OSHE)
A. OSHE
Office of Safety, Health and Environment
University Health Centre, Basement
20 Lower Kent Ridge Road
Singapore 119077
General Enquiries: 6516 1084
Fax: 6774 6979
Email: [email protected]
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www.nus.edu.sg/osh/
B. Faculty/ Department Safety and Health Officers/ Coordinators
Contacts for Safety & Health Officers/ Coordinators on safety and health issues pertaining to your faculty
are accessible at:
http://www.nus.edu.sg/osh/aboutus/staff.htm#staff_fac.
28 LIST OF APPENDICES
Appendix A Ionizing Radiation Occupational Dose Limits
Appendix B Radionuclide Exemption Quantity Limits
Appendix C Annual Limits on Intake (ALI) for Radiation Workers
Appendix D Limits for Contamination of Surfaces
Appendix E Request for Funding for Occupational Health Related Medical Services (OSHE/51/D01)
Appendix F Fact Sheets of Commonly Used Isotopes
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Appendix G Radioactive Package Receipt and Inspection Form (To be included soon)
Appendix H Radiation Machine Inspection and Survey Form
Appendix I Radioactive Material Inventory Form
Appendix J Standard Symbol For Designating Any Ionising Radiation Hazard
Appendix K Portable Radiation Survey Meter Operation Procedure
Appendix L Liquid Scintillation Counter Operation/Wipe Test Procedure
Appendix M Radioactive Material User Monthly Survey Form
Appendix N Radiation Dose Record Transfer Form (to be included soon)
Appendix O Request for Disposal of Radioactive Waste Form (OSHE/F/RS/01)
Appendix P Radioactive waste container label
Appendix Q Sealed Source Leak Test Procedure
Appendix S Radiation Laboratory Inspection Checklist (To be included soon)
Appendix T RPNSD Service Request Form
Appendix A: Ionizing Radiation Occupational Dose Limits
(Source: Second Schedule, Radiation Protection (Ionising Radiation) Regulations 2001)
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Appendix B: Radionuclide Exemption Quantitiy Limits
(Source: First Schedule, Radiation Protection (Ionising Radiation) Regulations 2001)
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Appendix C: Annual Limits on Intake (ALI) for Radiation Workers
(Source: Third Schedule, Radiation Protection (Ionising Radiation) Regulations 2001)
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Appendix D: Limits for Contamination of Surfaces
(Source: Fifth Schedule, Radiation Protection (Ionising Radiation) Regulations 2001)
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Appendix E: Request for Funding for Occupational Health Related Medical Services
(OSHE/51/D01)
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Appendix F: Fact Sheets of Commonly Used Isotopes
Tritium H-3:
Radiological half-life, T1/2 12.3 years
Principle emission 18.6 keV beta
(maximum)
Dose rate (1cm from a beta point source) 300 mrad/h per mCi
Biological monitoring method Urine samples
Range in air 4.7mm
Range in water 6x10"Jmm
Shielding required None
Monitoring method for contamination Wipe survey
Special Considerations:
Tritium compounds can be absorbed through the skin therefore labcoats and gloves
must always be worn. Consider wearing two pair of gloves and change them frequently.
Practice procedures without radioactivity prior to performing the procedure with H-3.
Practice will improve dexterity and speed, along with providing opportunity to determine
errors and practices that are not ALARA.
Work involving volatile forms of H-3 (e.g., gas, tritiated water) shall be performed in a
fume hood. Place previously opened containers of tritiated water into a fume hood, not a
refrigerator.
Monitor storage areas where large quantities of H-3 are kept, as certain forms tend to
"creep". Due to its low beta energy, tritium cannot be monitored directly, and
therefore regular wipe surveys of the work are recommended.
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Carbon -14 C-14:
Radiological half-life, Ti,2 5730 years
Principle emission 156eV beta (maximum)
Dose rate {1cm from a beta point source) 300 mrad/h per mCi
Biological monitoring method Breath or urine samples
Range in air 21.8cm
Range in water 0.28mm
Shielding required 1cm plexiglass
Monitoring method for contamination GM counter
Special Considerations:
Urinalysis: Not Required; however, prudent after a 14C radioactive spill or suspected
intake.
Inherent volatility (at STP): Not Significant.
Possibility of organic 14C compounds being absorbed through gloves.
Care should be taken NOT to generate CO2 gas which could be inhaled.
Internal Dose is the concern: Skin contamination, ingestion, inhalation, and puncture.
Always wear a lab coat and disposable gloves when working with 14C.
The concentration of carbon in adipose tissue, including the yellow marrow, is about 3
times the average whole body concentration. No other organ or tissue of the body
concentrates stable carbon to any significant extent.
The fractional absorption of dietary carbon (uptake to blood) is usually in excess of 0.90.
Three main classes of carbon compounds may be inhaled: organic compounds, gases (CO
or CO2), and aerosols of carbon containing compounds such as carbonates and carbides.
Organic Compounds - most organic compounds are NOT very volatile under normal
circumstances; the probability of these being inhaled as vapors is therefore small. In
circumstances where such substances are inhaled, it would be prudent to assume that once they
enter the respiratory system they are instantaneously and completely translocated to the systemic
circulation without changing their chemical form.
Gases - the inhalation of CO and its retention in body tissues has been studied extensively. Since
gas has a relatively low solubility in tissue water, doses due to absorbed gas in tissues are
insignificant in comparison with doses due to the retention of CO bound to hemoglobin. CO2 in
the blood exists mainly as a bicarbonate.
Carbonates & Carbides - It is assumed that inhaled or ingested 14C labeled compounds are
instantaneously and uniformly distributed throughout all organs & tissues of the body where they
are retained with a biological half-life of 12-40 days.
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Phosphorus-32 P-32:
Radiological half-life, JV2 14.3 days
Principle emission 1.71 MeVbeta
(maximum)
Dose rate (1cm from a beta point source) 300 mrad/h per mCi
Biological monitoring method Urine samples
Range in air 6.1m
Range in water 0.8cm
Shielding required 1cm plexiglass
Monitoring method for contamination GM counter
Special Considerations:
Avoid direct eye contact with the P-32 beta. Never look directly upon an unshielded
container of P-32. Eye protection (safety glasses or goggles) should be worn when
handling P-32 vials.
Plastic or other low Z material shielding and storage containers should be used to
minimize exposure from P-32. Do not use lead shielding, as it generates
bremsstrahlung X ray radiation.
Tweezers and Forceps and other remote handling tools should be used when handling P-
32.
Because of the high energy beta, the possibility of skin contamination or direct handling
of P-32 needs to be minimized. If skin contamination is detected decontamination needs
to be initiated immediately. Even low activities of P-32 skin contamination for a short
period of time can result in a significant dose to the skin.
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Sulphur-35 S-35:
Radiological half-life, T1/2 87.4 days
Principle emission 167 keV beta
(maximum)
Dose rate {1cm from a beta point source) 300 mrad/h per mCi
Biological monitoring method Urine samples
Range in air 26cm
Range in water 0.32mm
Shielding required 1cm plexiglass
Monitoring method for contamination GM counter
Special Considerations:
Plastic or other low Z material shielding and storage containers should be used to
minimize exposure from P-32. . Do not use lead shielding, as it generates
bremsstrahlung X Ray. Tweezers and Forceps and other remote handling tools should be
used when handling S-35 vials
Radiolysis may occur with S-35 amino acids (e.g., methionine) during storage, with a
resulting volatile impurity. New vials and closed vials that have been stored for a period
of time should be opened in a fume hood or through an activated charcoal filter. Volatile
impurities are generally small (0.05%).
If practical procedures involving the use of S-35 compounds should be in enclosed
containers because of the potential for production of volatile S-35 compounds. Routinely
check water baths and the inside of incubators for contamination during and after
procedures involving S-35.
Metabolic behavior of common S-35 labeled organic compounds may be considerably
different from common S-35 labeled inorganic compounds. This difference must be
considered if uptake occurs.
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Chromium-51 Cr-51:
Radiological half-life, Ty2 27.7 days
Principle emission 0.32 MeV gamma (9.8%),
5keV X-ray (22%)
Dose rate (1cm from a beta point source) 18R/h
Biological monitoring method Whole body count
Half-value layer 3mm lead
Monitoring method for contamination Nal or other scintillation detector
Use lead for shielding and storage materials.
Indirect viewing aids should be used to minimize exposure from Cr-51.
Tweezers and Forceps and other remote handling tools should be used when handling
Cr-51 Vials.
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Iodine-125 I-125:
Radiological half-life, Ty2 60 days
Principle emission 35keVgamma(7%), 27-
32keV X-ray (140%)
Dose rate (1cm from a point source) 1.4R/h
Biological monitoring method Thyroid scan
Half-value layer 0.02mm lead
Monitoring method for contamination Nal or other scintillation
detector
Use lead for shielding and storage materials.
Indirect viewing aids should be used to minimize exposure from I-125.
Tweezers and Forceps and other remote handling tools should be used when handling
I-125 Vials.
Unbound I-125 is inherently volatile. Work with unbound I-125 shall be performed in
a fume hood or well ventilated area. Iodinations shall be performed in a hood,
approved by the Radiation Safety Office and equipped with charcoal filter and
sampling apparatus.
Acidic and frozen solutions enhance radioiodine volatility. Keeps pH of solutions
containing I-125 at 7 or higher. Do not freeze solutions containing I-125.
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Appendix H: Radiation Machine Inspection and Survey Form
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Appendix I: Radioactive Material Inventory Form
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Appendix J: Standard Symbol For Designating Any Ionising Radiation Hazard
\
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Appendix K: Portable Radiation Survey Meter Operation Procedure
This section provides guidance on how to use portable survey meters for contamination
monitoring (using pancake GM, end window GM and NaI scintillation detectors) and exposure
monitoring (using Energy compensated GM and Ionization chamber detectors)
Scintillation radiation detectors are very shock sensitive and fragile. GM detectors have very thin
windows that can be easily punctured by sharp objects. So handle the detectors with care. Do not
keep survey meters in fume hoods or cabinets in which you use or store corrosives; the fumes can
quickly render the instrument useless. If the instrument will not be used for an extended period of
time, remove the batteries and attach a tag stating that batteries have been removed. Many
instruments work best if the humidity is low. High humidity may cause the meter to read much
higher than background even when no radiation source is present. A small container or porous bag
of silica gel desiccant placed inside the instrument's case may prevent problems. Inspect color-
indicating silica gel frequently for color change.
Prior to using any radiation detector, read the operating manual to become familiar with the
controls and operating characteristics. Before using the meter, ensure you are wearing appropriate
PPE (gloves, lab coat, goggles etc.,)
Check the meter to determine if the calibration sticker is current. Meters must be calibrated
annually (at least once per year) and records should be kept for the past three years. Meters
cannot be calibrated by the Office of Safety Health and Environment and must be sent to an
approved calibration service.
RPNSD provides calibration service and the meter can be taken to RPNSD office located at
Level 3, Annexe Bldg 40 Scotts Road. The RPNSD Service Request Form found in Appendix T
should be completed and submitted to RPNSD along with a cheque for SGD 141.75 service
charge per meter.
Inspect the physical condition and make sure there are no cracks or dents on the probe. Use a
known sample radiation source and observe the response of the probe.
Ensure the instrument has sufficient battery life. Corrosion from batteries or corrosive
atmospheres can destroy an instrument quickly. Replace low batteries promptly and perform a
visual check occasionally.
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Determine the background count-rate/exposure rate so you can compare your survey results with a
"background" measurement. The background measurement should be performed preferably outside
the lab or areas where no radiation sources are present.
For contamination monitoring:
The background rate for a pancake or end window GM meter should be less than 100 counts per
minute while the background reading for a NaI meter should be less than 400 counts per minute. If
background readings exceed these levels, investigate the area for unknown sources of radiation or
detector contamination. Do not use the survey meter if it does not register a background count. With
speaker on, point the probe window at the area or equipment you wish to monitor for radiation or
radioactive contamination. Do not cover the probe surface with parafilm or other protective coating.
Parafilm and similar materials will shield the low energy betas from C-14, P-33 and S-35 and may
prevent the meter from detecting contamination.
For exposure monitoring:
The background exposure rate is typically in the range of 20-30 µR/hr. All areas accessed by non
radiation workers should be always less than 50 µR/hr.
Since the response time for pancake GM, End Window GM and Energy Compensated GM
detectors are slow, they may take 10 seconds or more to reach 90% of final value. Scintillation
detectors do not suffer from slow response. All surveys are conducted by slowly passing the probe
over the area or equipment to be surveyed. Be certain to survey at a constant speed -
approximately 2 cm/sec. The distance from the surface or object should also be constant. A
distance of 1 cm is suggested. Be careful not to contaminate the probe itself. Observe the reading
on the detector.
(Note: If your detector has scale multipliers (e.g., x 0.1, x 1, x 10, etc.), the background and
actual measurement should be multiplied by this multiplier to obtain the correct reading. , if the
needle is on 300 and the multiplier is on the "X 0.1" scale, the rate is 300 x 0.1 = 30. The units
depends on whether you are using a contamination monitor or exposure rate monitor.
Contamination monitors have units of Counts per minute (CPM) and exposure rate monitors
usually have rates of (mR/hr). Usually, start with the lowest scale multiplier and move to the
higher scale. if the needle “pegs” the scale.)
At very high counting rates, pancake GM, End Window GM and energy compensated GM
detectors may become "saturated" and the meter reading will fall to zero, potentially causing a
false sense of security. When performing surveys where high levels of contamination or high
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radiation levels are expected, always approach the area cautiously with the survey meter turned
on. A rapid increase in the meter reading followed by a drop to zero indicates a high radiation
field. Saturation may occur when measuring radiation fields resulting from a few µcuries of P-32.
Scintillation detectors do not suffer from “saturation” effect.
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Appendix L: Liquid Scintillation Counter Operation/Wipe Test Procedure
Removable contamination is best identified by a wipe survey.
Wear appropriate PPE including gloves and lab coat before performing the survey. You should
change the gloves during the survey if you suspect the gloves might have become contaminated
while performing the survey. This ensures that you will not cross-contaminate any wipe samples.
Perform a wipe survey by rubbing a filter paper (approximately 45mm in diameter) or cotton swab
over the survey area with moderate pressure. The paper or swab may be wetted with ethanol or water
to increase the collection efficiency.
Usually an area of 100 cm2 is surveyed. To monitor a larger area, take additional wipes. ALWAYS
assign a number to each wipe AND make a sketch or use some other type of record to indicate
where each individual wipe sample was taken.
Deposit wipe sample into a clean scintillation vial. Fill the vial at least 2/3-full with scintillation
cocktail. Tightly cap the vial. Mix the contents of the vial thoroughly. Count the sample for at
least 1 minute in a liquid scintillation counter. ALWAYS INCLUDE A "BACKGROUND"
VIAL. Examine the counting results.
The net sample count rate is determined by subtracting the background count rate from the gross
count rate.
Sample activity is determined by dividing the net sample count rate by the instrument's efficiency for
the isotope in question.
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Appendix M: Radioactive Material User Monthly Survey Form
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Appendix O: Request for Disposal of Radioactive Waste Form (OSHE/F/RS/01)
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Appendix P: Radioactive waste container label
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Appendix Q: Sealed Source Leak Test Procedure
Sealed Source Leak Testing
It is required under the Radiation Protection (Ionizing Radiation) Regulations that all sealed
radioactive sources used in gauges etc be leak tested once in 12 months.
The sample for such test (known as Leak Test Sample) may be from the following as spelt out in
the Radiation Protection (Ionizing Radiation) Regulations 29(1a) :
1) Every immediate container or bonding which forms part of the sealed source; OR
2) Every container in which such a sealed source is permanently installed but which does not
form part of the sealed source.
As most sealed radioactive sources are used in gauges for level monitoring etc, the sample for the
leak test will most likely be categorised under 2) above.
Items needed for collection of Leak Test Samples.
1) A list of all sealed radioactive sources used in gauges must be maintained and kept
updated to show exact number of such sources.
2) Calibrated & working radiation survey meter
3) Tongs / Forceps / Tweezers etc.
4) Regular cotton wool
5) Laboratory grade ethanol (Alcohol)
6) Sealable plastic bags (recommended size : 8cm x 11cm)
7) Labels for the sealable plastic bags ; permanent marker can also be used to mark the bags.
8) Disposable Gloves
Procedures for collection of Leak Test Samples from Sealed Sources
1) Approach the sealed radioactive source with a calibrated & working survey meter to
ensure that radiation levels are within limits.
Levels are considered within limits(Radiation Protection (Ionizing Radiation) Regulations
24(3a,3b)) if they are :
Location
Levels
Up to 1 metre from source housing
4 - 20
5cm from surfaces of source housing
40 - 200
Important : When measuring, do not place hand across path of radiation beam.
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2) After the levels are ascertained, check the isotope & serial number of the source against
the list you have. If number & isotope tallies, record the radiation level measured against
it.
3) Tear off some cotton and make up a ball of about 2 - 3cm diameter and use a tong,
tweezer or forcep to hold it.
4) Moisten the cotton ball lightly with alcohol.
5) The moistened cotton ball is then used to wipe the external surfaces of the gauge
particularly the joints between the source housing and the structure holding it.
6) After wiping, the cotton ball is put into a sealable plastic bag which had been properly
labelled with the isotope name, serial number and activity of the radioactive source.
(DO NOT TOUCH THE COTTON BALL AFTER WIPING)
7) The samples can either be tested yourself using a liquid scintillation counter or can be
sent to RPNSD for testing.
a) For self analysis, please refer to Appendix L for liquid scintillation counter
operation and wipe test procedure. The leak test results must be recorded in the
Sealed source leak test form provided in Appendix R.
b) For RPNSD testing, the samples in the sealable plastic bags are then sent to the
Radiation Protection & Nuclear Science Department (RPNSD), The National
Environment Agency for analysis. RPNSD is located at Level 3, Annexe Bldg 40
Scotts Road. The cost of the wipe test analysis is SGD 57.75
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Appendix R: Sealed Source Leak Test Report
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Appendix T: RPNSD Service Request Form
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